/*  Part of SWI-Prolog

    Author:        Jan Wielemaker
    E-mail:        J.Wielemaker@vu.nl
    WWW:           http://www.swi-prolog.org
    Copyright (c)  2017-2025, VU University Amsterdam
			      CWI, Amsterdam
			      SWI-Prolog Solutions b.v.
    All rights reserved.

    Redistribution and use in source and binary forms, with or without
    modification, are permitted provided that the following conditions
    are met:

    1. Redistributions of source code must retain the above copyright
       notice, this list of conditions and the following disclaimer.

    2. Redistributions in binary form must reproduce the above copyright
       notice, this list of conditions and the following disclaimer in
       the documentation and/or other materials provided with the
       distribution.

    THIS SOFTWARE IS PROVIDED BY THE COPYRIGHT HOLDERS AND CONTRIBUTORS
    "AS IS" AND ANY EXPRESS OR IMPLIED WARRANTIES, INCLUDING, BUT NOT
    LIMITED TO, THE IMPLIED WARRANTIES OF MERCHANTABILITY AND FITNESS
    FOR A PARTICULAR PURPOSE ARE DISCLAIMED. IN NO EVENT SHALL THE
    COPYRIGHT OWNER OR CONTRIBUTORS BE LIABLE FOR ANY DIRECT, INDIRECT,
    INCIDENTAL, SPECIAL, EXEMPLARY, OR CONSEQUENTIAL DAMAGES (INCLUDING,
    BUT NOT LIMITED TO, PROCUREMENT OF SUBSTITUTE GOODS OR SERVICES;
    LOSS OF USE, DATA, OR PROFITS; OR BUSINESS INTERRUPTION) HOWEVER
    CAUSED AND ON ANY THEORY OF LIABILITY, WHETHER IN CONTRACT, STRICT
    LIABILITY, OR TORT (INCLUDING NEGLIGENCE OR OTHERWISE) ARISING IN
    ANY WAY OUT OF THE USE OF THIS SOFTWARE, EVEN IF ADVISED OF THE
    POSSIBILITY OF SUCH DAMAGE.
*/

#include "pl-incl.h"
#include "pl-comp.h"
#include "pl-arith.h"
#include "pl-tabling.h"
#include "pl-copyterm.h"
#include "pl-wrap.h"
#include "pl-event.h"
#include "pl-allocpool.h"
#include "pl-dbref.h"
#include "pl-prims.h"
#include "pl-gc.h"
#include "pl-fli.h"
#include "pl-wam.h"
#include "pl-proc.h"
#include "pl-pro.h"
#include "pl-write.h"
#include "pl-util.h"
#include "pl-supervisor.h"
#include "os/pl-prologflag.h"
#include "pl-termhash.h"
#include "pl-variant.h"
#include "pl-index.h"

/* - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - -
We provide two answer completion strategies:

  - Eager AC: #define O_AC_EAGER 1
    Complete each component fully before continuing to the next.
  - Lazy AC:  #undef O_AC_EAGER
    Only complete the leader of a component.  This is what XSB is
    doing.
- - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - */

#define O_AC_EAGER 1
// #undef O_AC_EAGER

#define record_t fastheap_term *
#define PL_record(t)      term_to_fastheap(t)
#define PL_recorded(r, t) put_fastheap(r, t)
#define PL_erase(r)	  free_fastheap(r)

#define SINDEX_MAX	32

typedef struct sindex_key
{ unsigned	argn;
  unsigned	key;
} sindex_key;

typedef struct suspension
{ record_t	term;		/* dependency/5 term with TNOT flag */
  record_t	instance;	/* Filter for call subsumption */
  sindex_key   *keys;		/* Index to find filter candidates */
} suspension;

typedef struct answer
{ trie_node    *node;		/* Point into answer trie */
} answer;

typedef struct
{ worklist     *list;		/* worklist we enumerate */
  cluster      *acp;		/* Current answer cluster */
  cluster      *scp;		/* Current suspension cluster */
  answer       *answer;		/* Current answer */
  int		acp_index;	/* Index in anser cluster */
  struct
  { suspension *base;
    suspension *top;
    suspension *here;
  } suspensions;
  int		keys_inited;	/* #Initialized keys */
  sindex_key	keys[SINDEX_MAX]; /* suspension matching */
} wkl_step_state;

#if USE_LD_MACROS
#define	tbl_create_subcomponent(leader)			LDFUNC(tbl_create_subcomponent, leader)
#define	wkl_add_answer(wl, node)			LDFUNC(wkl_add_answer, wl, node)
#define	wkl_mode_add_answer(wl, trie, answer, delays)	LDFUNC(wkl_mode_add_answer, wl, trie, answer, delays)
#define	tbl_put_moded_args(t, node)			LDFUNC(tbl_put_moded_args, t, node)
#define	unify_skeleton(trie, wrapper, skel)		LDFUNC(unify_skeleton, trie, wrapper, skel)
#define	idg_init_variant(atrie, def, variant)		LDFUNC(idg_init_variant, atrie, def, variant)
#define	unify_component_status(t, scc)			LDFUNC(unify_component_status, t, scc)
#define	idg_add_edge(atrie, ctrie)			LDFUNC(idg_add_edge, atrie, ctrie)
#define	idg_set_current_wl(wlref)			LDFUNC(idg_set_current_wl, wlref)
#define	claim_answer_table(atrie, clrefp, flags)	LDFUNC(claim_answer_table, atrie, clrefp, flags)
#define	table_status_reeval_wait(atrie)			LDFUNC(table_status_reeval_wait, atrie)
#define	tripwire_answers_for_subgoal(wl)		LDFUNC(tripwire_answers_for_subgoal, wl)
#define	generalise_answer_substitution(spec, gen)	LDFUNC(generalise_answer_substitution, spec, gen)
#define	new_mdep(t)					LDFUNC(new_mdep, t)
#define	tt_has_modified_dependencies(atrie)		LDFUNC(tt_has_modified_dependencies, atrie)
#define	tt_add_table(atrie, flags)			LDFUNC(tt_add_table, atrie, flags)
#define	atrie_answer_event(atrie, node)			LDFUNC(atrie_answer_event, atrie, node)
#define	inner_is_monotonic(_)				LDFUNC(inner_is_monotonic, _)
#define	mono_queue_answer(atrie, ans, an)		LDFUNC(mono_queue_answer, atrie, ans, an)
#define	force_reeval(n)					LDFUNC(force_reeval, n)
#define find_dep(mdep, dep, found)			LDFUNC(find_dep, mdep, dep, found)
#endif /*USE_LD_MACROS*/

#define LDFUNC_DECLARATIONS

static bool	destroy_answer_trie(trie *atrie);
static void	free_worklist(worklist *wl);
static void	clean_worklist(worklist *wl);
static void	destroy_depending_worklists(worklist *wl0);
static void	free_worklist_set(worklist_set *wls, int freewl);
static void	add_global_worklist(worklist *wl);
static tbl_component *tbl_create_subcomponent(trie *leader);
static worklist *tbl_add_worklist(trie *atrie, tbl_component *scc);
static int	wl_has_work(const worklist *wl);
static cluster *new_answer_cluster(worklist *wl, answer *first);
static void	wkl_append_left(worklist *wl, cluster *c);
static int	wkl_add_answer(worklist *wl, trie_node *node);
static trie_node* wkl_mode_add_answer(worklist *wl, trie *trie, term_t answer,
				      term_t delays);
static int	tbl_put_moded_args(term_t t, trie_node *node);
static void	del_child_component(tbl_component *parent, tbl_component *child);
static void	free_components_set(component_set *cs, int destroy);
static bool	unify_skeleton(trie *trie, term_t wrapper, term_t skel);
#ifdef O_DEBUG
static void	print_worklist(const char *prefix, worklist *wl);
static void	print_delay(const char *msg,
			    trie_node *variant, trie_node *answer);
static void	print_answer(const char *msg, trie_node *answer);
static bool	put_delay_info(term_t t, trie_node *answer);
static void	print_answer_table(trie *atrie, const char *msg, ...);
#endif
static int	simplify_component(tbl_component *scc);
static void	idg_destroy(idg_node *node);
static void	idg_reset(idg_node *node);
static int	idg_init_variant(trie *atrie, Definition def, term_t variant);
static void	reeval_complete(trie *atrie);
static void	reset_reevaluation(trie *atrie);
static int	unify_component_status(term_t t, tbl_component *scc);
static int	simplify_answer(worklist *wl, trie_node *answer, int truth);
static bool	table_is_incomplete(trie *trie);
static int	idg_add_edge(trie *atrie, trie *ctrie);
static int	idg_set_current_wl(term_t wlref);
#ifdef O_PLMT
static int	claim_answer_table(trie *atrie, atom_t *clrefp,
				   int flags);
#endif
static atom_t	table_status_reeval_wait(trie *atrie);
static atom_t	tripwire_answers_for_subgoal(worklist *wl);
static int	generalise_answer_substitution(term_t spec, term_t gen);
static int	add_answer_count_restraint(void);
static int	add_radial_restraint(void);
static int	tbl_wl_tripwire(worklist *wl, atom_t action, atom_t wire);
static int	tbl_pred_tripwire(Definition def, atom_t action, atom_t wire);
static idg_mdep *new_mdep(term_t t);
static void	free_mdep(idg_mdep *mdep);
static void	mdep_empty_queue(idg_mdep *mdep, size_t del);
static void	mdep_empty_queues(idg_mdep *mdep);
static int	mdep_unify_answers(term_t t, idg_mdep *mdep);
static void	prune_deleted_mdeps(idg_node *idg);
static void	tt_abolish_table(trie *atrie);
static int	tt_has_modified_dependencies(trie *atrie);
static void	tt_add_table(trie *atrie, int flags);
static int	atrie_answer_event(trie *atrie, trie_node *node);
static table_props *get_predicate_table_props(Definition def);
static int	inner_is_monotonic(void);
static int	mono_queue_answer(trie *atrie, term_t ans, word an);
static void	force_reeval(idg_node *n);
static int	idg_changed(trie *atrie, int flags);
static trie    *idg_propagate_change(idg_node *n, int flags);
static int	find_dep(idg_mdep *mdep, term_t dep, idg_mdep **found);
#undef LDFUNC_DECLARATIONS

#define WL_IS_SPECIAL(wl)  (((intptr_t)(wl)) & 0x1)
#define WL_IS_WORKLIST(wl) ((wl) && !WL_IS_SPECIAL(wl))

#define WL_GROUND   ((worklist *)0x21)
#define WL_DYNAMIC  ((worklist *)0x41)

#define WLFS_FREE_NONE		0x0000
#define WLFS_KEEP_COMPLETE	0x0001
#define WLFS_FREE_ALL		0x0002
#define WLFS_DISCARD_INCOMPLETE	0x0004

#define DV_DELETED		((trie*)0x1)
#define DL_UNDEFINED		((delay_info*)0x1)

#define DL_IS_DELAY_LIST(dl)	((dl) && (dl) != DL_UNDEFINED)

#define IDG_CHANGED_NODE	0x0001		/* Normal node change */
#define IDG_CHANGED_MONO	0x0002		/* Monotonic node change */
#define IDG_PROPAGATE_FORCE	0x0004		/* See (**) */

#ifdef O_PLMT
#define	LOCK_SHARED_TABLE(t)	countingMutexLock(&GD->tabling.mutex);
#define	UNLOCK_SHARED_TABLE(t)	countingMutexUnlock(&GD->tabling.mutex);

static inline void
drop_trie(trie *atrie)
{
#ifdef O_DEBUG
  int mytid = PL_thread_self();
  assert(mytid == atrie->tid);
  int rc = COMPARE_AND_SWAP_INT(&atrie->tid, mytid, 0);
  assert(rc);
#else
  atrie->tid = 0;
#endif
}

static inline void
take_trie(trie *atrie, int tid)
{ assert(atrie->data.worklist != WL_DYNAMIC);
#ifdef O_DEBUG
  int rc = COMPARE_AND_SWAP_INT(&atrie->tid, 0, tid);
  assert(rc);
#else
  atrie->tid = tid;
#endif
}

#define COMPLETE_WORKLIST(__trie, __code) \
	do \
	{ LOCK_SHARED_TABLE(__trie); \
	  if ( __trie->tid ) \
	  { DEBUG(0, assert(__trie->tid == PL_thread_self())); \
	  } else \
	  { take_trie(__trie, PL_thread_self()); \
	  } \
	  __code; \
	  drop_trie(__trie); \
	  cv_broadcast(&GD->tabling.cvar); \
	  UNLOCK_SHARED_TABLE(__trie); \
	} while(0)

static int	wait_for_table_to_complete(trie *atrie);
static int	table_needs_work(trie *atrie);
static void	register_waiting(int tid, trie *atrie);
static void	unregister_waiting(int tid, trie *atrie);
static int	is_deadlock(trie *atrie);

#else /*O_PLMT*/

#define COMPLETE_WORKLIST(__trie, __code) \
	do { __code; } while(0)

#endif /*O_PLMT*/


		 /*******************************
		 *	     COMPONENTS		*
		 *******************************/

static tbl_component *
new_component(void)
{ tbl_component *c = PL_malloc(sizeof(*c));

  memset(c, 0, sizeof(*c));
  c->magic = COMPONENT_MAGIC;

  return c;
}

#define FC_DESTROY	0x0001
#define FC_CHILD	0x0002

static void
push_component_set(segstack *stack, component_set *cs)
{ tbl_component **bp = baseBuffer(&cs->members, tbl_component*);
  tbl_component **tp = topBuffer(&cs->members, tbl_component*);
  typedef struct tbl_component *Component;

  for(; bp < tp; bp++)
  { if ( !pushSegStack(stack, *bp, Component) )
      outOfCore();
  }

  discardBuffer(&cs->members);
  PL_free(cs);
}

static void
free_component(tbl_component *c, int flags)
{ GET_LD
  assert(c->magic == COMPONENT_MAGIC);
  c->magic = 0;
  segstack stack;
  typedef struct tbl_component *Component;
  Component buf[100];

  if ( c == LD->tabling.component )
  { LD->tabling.component = c->parent;
    if ( !c->parent && LD->tabling.has_scheduling_component )
      LD->tabling.has_scheduling_component = false;
  }

  initSegStack(&stack, sizeof(Component), sizeof(buf), buf);
  if ( !pushSegStack(&stack, c, Component) )
    outOfCore();

  while( popSegStack(&stack, &c, Component) )
  { if ( !(flags&FC_CHILD) && c->parent )
      del_child_component(c->parent, c);
    flags |= FC_CHILD;				/* only for the first */
    if ( c->worklist )
      free_worklist_set(c->worklist, WLFS_FREE_NONE);
    if ( c->delay_worklists )
      free_worklist_set(c->delay_worklists, WLFS_FREE_NONE);
    if ( c->created_worklists )
      free_worklist_set(c->created_worklists, WLFS_FREE_ALL);
    if ( c->children )
      push_component_set(&stack, c->children);
    if ( c->merged )
      push_component_set(&stack, c->merged);

    PL_free(c);
  }

  clearSegStack(&stack);
}


static void
add_child_component(tbl_component *parent, tbl_component *child)
{ component_set *cs;

  if ( !(cs=parent->children) )
  { cs = PL_malloc(sizeof(*cs));
    initBuffer(&cs->members);
    parent->children = cs;
  }

  addBuffer(&cs->members, child, tbl_component*);
}

static void
del_child_component(tbl_component *parent, tbl_component *child)
{ component_set *cs;

  if ( (cs=parent->children) )			/* can be merged */
  { tbl_component **bp = baseBuffer(&cs->members, tbl_component*);
    tbl_component **tp = topBuffer(&cs->members, tbl_component*);

    for(; *bp != child && bp < tp; bp++)
      ;
    if ( bp < tp )
    { memmove(bp, bp+1, (tp-bp-1)*sizeof(*bp));
      (void)popBuffer(&cs->members, tbl_component*);
    }
  }
}

static void
free_components_set(component_set *cs, int flags)
{ if ( (flags & FC_DESTROY) )
  { tbl_component **bp = baseBuffer(&cs->members, tbl_component*);
    tbl_component **tp = topBuffer(&cs->members, tbl_component*);

    for(; bp < tp; bp++)
      free_component(*bp, flags);
  }

  discardBuffer(&cs->members);
  PL_free(cs);
}

/* - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - -
Merge all subcomponets of c into c.   The properties of the subcomponets
are destroyed and .status is set to SCC_MERGED.
- - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - */

static void merge_children(tbl_component *c, tbl_component *m);
static void merge_one_component(tbl_component *c, tbl_component *m);
static void wls_set_component(worklist_set *wls, size_t size0, tbl_component *c);

static size_t
wls_size(const worklist_set *wls)
{ return wls ? entriesBuffer(&wls->members, worklist*) : 0;
}


static void
merge_component(tbl_component *c)
{ size_t s_global  = wls_size(c->worklist);
  size_t s_created = wls_size(c->created_worklists);

  if ( c->children )
    merge_children(c, c);

  wls_set_component(c->worklist, s_global, c);
  wls_set_component(c->created_worklists, s_created, c);

  DEBUG(MSG_TABLING_MERGE,
	Sdprintf("Grown SCC %p from %zd to %zd worklists\n",
		 c, s_created, wls_size(c->created_worklists)));
}


static void
wl_set_component(worklist *wl, tbl_component *c)
{ wl->component = c;
  wl->executing = false;
  if ( !wl->in_global_wl && wl_has_work(wl) )
    add_global_worklist(wl);
  if ( wl->negative )
  { DEBUG(MSG_TABLING_MERGE,
	  Sdprintf("Merging negative literal into SCC %zd\n",
		   pointerToInt(c)));
    if ( c->neg_status == SCC_NEG_NONE )
      c->neg_status = SCC_NEG_DELAY;
    else if ( c->neg_status == SCC_NEG_SIMPLIFY )
      c->neg_status = SCC_NEG_DELAY;
  }
}


static void
wls_set_component(worklist_set *wls, size_t size0, tbl_component *c)
{ worklist **base = baseBuffer(&wls->members, worklist*);
  worklist **top  = topBuffer(&wls->members, worklist*);

#ifdef O_DEBUG
  size_t old = 0;
  for(; base < top; base++, old++)
  { if ( old < size0 )
      assert((*base)->component == c);
    else
      wl_set_component(*base, c);
  }
#else
  base += size0;			/* skip old ones */
  for(; base < top; base++)
    wl_set_component(*base, c);
#endif
}

static void
merge_component_sets(component_set **into, component_set **from)
{ typedef tbl_component* Component;

  if ( *into && *from )
  { tbl_component **s = baseBuffer(&(*from)->members, tbl_component*);
    size_t        cnt = entriesBuffer(&(*from)->members, tbl_component*);
    Buffer	    b = &(*into)->members;

    addMultipleBuffer(b, s, cnt, Component);
    free_components_set(*from, 0);
    *from = NULL;
  } else if ( *from )
  { *into = *from;
    *from = NULL;
  }
}


/* Merge all components of cs into c */

static void
merge_children(tbl_component *c, tbl_component *m)
{ component_set *cs;

  if ( (cs=m->children) )
  { tbl_component **bp = baseBuffer(&cs->members, tbl_component*);
    tbl_component **tp = topBuffer(&cs->members, tbl_component*);

    for( ; bp < tp; bp++)
      merge_one_component(c, *bp);

    merge_component_sets(&m->merged, &m->children);
  }
}


static void
merge_worklists(worklist_set **into, worklist_set **from)
{ typedef worklist* Worklist;

  if ( *into && *from )
  { worklist **s = baseBuffer(&(*from)->members, worklist*);
    size_t   cnt = entriesBuffer(&(*from)->members, worklist*);
    Buffer     b = &(*into)->members;

    addMultipleBuffer(b, s, cnt, Worklist);
    free_worklist_set(*from, WLFS_FREE_NONE);
    *from = NULL;
  } else if ( *from )
  { *into = *from;
    *from = NULL;
  }
}


static void
merge_one_component(tbl_component *c, tbl_component *m)
{ assert(m->magic == COMPONENT_MAGIC);

  if ( m->status != SCC_ACTIVE )
    return;

  merge_children(c, m);

  DEBUG(MSG_TABLING_MERGE,
	Sdprintf("Merged %zd into %zd, %zd worklists, %zd created\n",
		 pointerToInt(m), pointerToInt(c),
		 entriesBuffer(&m->worklist->members, worklist*),
		 entriesBuffer(&m->created_worklists->members, worklist*)));

  merge_worklists(&c->worklist, &m->worklist);
  merge_worklists(&c->created_worklists, &m->created_worklists);
  merge_worklists(&c->delay_worklists, &m->delay_worklists);

  m->status = SCC_MERGED;
}

		 /*******************************
		 *           WORKLISTS		*
		 *******************************/

static worklist_set *
new_worklist_set(worklist *wl)
{ worklist_set *wls = PL_malloc(sizeof(*wls));

  initBuffer(&wls->members);
  addBuffer(&wls->members, wl, worklist*);

  return wls;
}


static void
add_global_worklist(worklist *wl)
{ tbl_component *c = wl->component;
  worklist_set *wls;

  if ( !(wls=c->worklist) )
    c->worklist = new_worklist_set(wl);
  else
    addBuffer(&wls->members, wl, worklist*);

  wl->in_global_wl = true;
}


static void
add_delay_worklist(worklist *wl)
{ tbl_component *c = wl->component;
  worklist_set *wls;

  if ( !(wls=c->delay_worklists) )
    c->delay_worklists = new_worklist_set(wl);
  else
    addBuffer(&wls->members, wl, worklist*);
}


/* - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - -
Normal completion is done. There  may   be  worklists that are suspended
using negation_suspend/3. We wake  these  up   by  adding  a  new answer
cluster with a NULL node.
- - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - */

#define negative_worklist(scc) LDFUNC(negative_worklist, scc)
static worklist *
negative_worklist(DECL_LD tbl_component *scc)
{ if ( scc->delay_worklists )
  { while( !isEmptyBuffer(&scc->delay_worklists->members) )
    { worklist *wl = popBuffer(&scc->delay_worklists->members, worklist*);

      if ( !wl->has_answers )	/* we have an unconditional answers, so no delay */
      { cluster *c;
	answer ans = {NULL};

	wl->neg_delayed = true;
	DEBUG(MSG_TABLING_NEG,
	      { term_t t = PL_new_term_ref();
		unify_trie_term(wl->table->data.variant, NULL, t);
		Sdprintf("Resuming negative node with delay list %zd: ",
			 pointerToInt(wl));
		PL_write_term(Serror, t, 999, PL_WRT_NEWLINE);
	      });

	c = new_answer_cluster(wl, &ans);
	wkl_append_left(wl, c);
	if ( !wl->riac )
	  wl->riac = c;

	return wl;
      }
    }

    scc->neg_status = SCC_NEG_SIMPLIFY;
  }

#ifdef O_DEBUG
  if ( !DEBUGGING(TABLING_NO_SIMPLIFY) )
  { simplify_component(scc);
  } else
  { Sdprintf("Skipping (TABLING_NO_SIMPLIFY) simplifiation for SCC %zd\n",
	     pointerToInt(scc));
  }
#else
  simplify_component(scc);
#endif

  return NULL;
}


static int
wl_has_work(const worklist *wl)
{ return wl->riac && wl->riac->next;
}

#define pop_worklist(c) LDFUNC(pop_worklist, c)
static worklist *
pop_worklist(DECL_LD tbl_component *c)
{ worklist_set *wls = c->worklist;

  if ( wls )
  { while( !isEmptyBuffer(&wls->members) )
    { worklist *wl = popBuffer(&wls->members, worklist*);
      wl->in_global_wl = false;

      if ( wl_has_work(wl) )
	return wl;
    }
  }

  return NULL;
}


static void
reset_global_worklist(tbl_component *c)
{ worklist_set *wls;

  if ( c && (wls = c->worklist) )
  { c->worklist = NULL;
    free_worklist_set(wls, WLFS_FREE_NONE);
  }
}


static void
add_newly_created_worklist(worklist *wl)
{ tbl_component *c = wl->component;
  worklist_set *wls;

  if ( !(wls=c->created_worklists) )
  { wls	= c->created_worklists = PL_malloc(sizeof(*c->created_worklists));
    initBuffer(&wls->members);
  }

  addBuffer(&wls->members, wl, worklist*);
}

static void
reset_newly_created_worklists(tbl_component *c, int flags)
{ worklist_set *wls;

  if ( c && (wls = c->created_worklists) )
  { c->created_worklists = NULL;
    free_worklist_set(wls, flags);
  }
}

static size_t
worklist_set_to_array(worklist_set *wls, worklist ***wlp)
{ if ( wls )
  { *wlp = (worklist**)baseBuffer(&wls->members, worklist*);
    return entriesBuffer(&wls->members, worklist*);
  } else
  { *wlp = NULL;
    return 0;
  }
}

static void
free_worklist_set(worklist_set *wls, int freewl)
{ if ( freewl )
  { worklist **wlp = (worklist**)baseBuffer(&wls->members, worklist*);
    size_t i, nwpl = entriesBuffer(&wls->members, worklist*);

    for(i=0; i<nwpl; i++)
    { worklist *wl = wlp[i];

      if ( (freewl&WLFS_FREE_ALL) || ison(wl->table, TRIE_COMPLETE) )
      { free_worklist(wl);
      } else if ( (freewl&WLFS_DISCARD_INCOMPLETE) )
      { trie *atrie = wl->table;

	if ( atrie->data.IDG && atrie->data.IDG->reevaluating )
	{ atrie->data.worklist = NULL;
	  free_worklist(wl);
	  reset_reevaluation(atrie);
	} else
	{ if ( table_is_incomplete(atrie) )
	  { DEBUG(MSG_TABLING_EXCEPTION,
		  print_answer_table(atrie, "Deleting incomplete answer table"));
	    destroy_answer_trie(atrie);
	  }
	}
      }
    }
  }

  discardBuffer(&wls->members);
  PL_free(wls);
}


		 /*******************************
		 *	 TABLE DELAY LISTS	*
		 *******************************/

#ifdef O_DEBUG
static void print_dl_dependency(trie *from, trie *to);
#endif

static inline trie_node *
REC_DELAY(record_t r)
{ return (trie_node*)(((uintptr_t)r)|0x1);
}

static inline record_t
UNREC_DELAY(trie_node *r)
{ return (record_t)(((uintptr_t)r)&~(uintptr_t)1);
}

static int
IS_REC_DELAY(trie_node *r)
{ return (uintptr_t)r & 0x1;
}

int
answer_is_conditional(trie_node *answer)
{ delay_info *di;

  return ( (di=answer->data.delayinfo) &&
	   (di == DL_UNDEFINED || !isEmptyBuffer(&di->delay_sets)) );
}

static delay_info *
answer_delay_info(worklist *wl, trie_node *answer, int create)
{ delay_info *di;

  if ( (di=answer->data.delayinfo) )
  { return di;
  } else if ( !create )
  { return NULL;
  } else if ( (di=malloc(sizeof(*di))) )
  { di->variant = wl->table->data.variant;
    di->has_share_records = false;
    initBuffer(&di->delay_sets);
    initBuffer(&di->delays);
    answer->data.delayinfo = di;
    wl->undefined++;

    return di;
  } else
  { return NULL;
  }
}


/* - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - -
destroy_delay_info(trie_node  *answer,  int  propagate)    removes   and
deallocates the delay info  that  may   be  associated  to  `answer`. If
`propagate` is true, it also removes   the backpointers to `answer` from
the worklist `delay` buffer of worklists   that  are references from the
delay elements.
- - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - */

static void
delete_answer(Buffer ab,  trie_node *answer)
{ trie_node **ap = baseBuffer(ab, trie_node*);
  trie_node **ep = topBuffer(ab, trie_node*);
  trie_node **op = ap;

  for(; ap < ep; ap++)
  { if ( *ap != answer )
      *op++ = *ap;
  }

  ab->top = (char*)op;
}

static void
destroy_delay_info(trie *atrie, trie_node *answer, int propagate)
{ delay_info *di = answer->data.delayinfo;

  if ( DL_IS_DELAY_LIST(di) )
  { answer->data.delayinfo = NULL;
    if ( di->has_share_records )
    { delay *d = baseBuffer(&di->delays, delay);
      delay *z = topBuffer(&di->delays, delay);

      for(; d < z; d++)		/* keep a flag to see whether we have these */
      { if ( IS_REC_DELAY(d->answer) )
	  PL_erase(UNREC_DELAY(d->answer));
      }
    }

    if ( propagate )
    { delay *db = baseBuffer(&di->delays, delay);
      delay *dt = topBuffer(&di->delays, delay);
      delay *d;

      for(d=db; d < dt; d++)
      { trie *at;

	if ( (at=d->variant) && at != DV_DELETED )
	{ worklist *wl = at->data.worklist;

	  if ( WL_IS_WORKLIST(wl) && !isEmptyBuffer(&wl->delays) )
	  { DEBUG(MSG_TABLING_VTRIE_DEPENDENCIES,
		  { GET_LD
		    term_t tab = PL_new_term_ref();
		    term_t dep = PL_new_term_ref();
		    unify_trie_term(atrie->data.variant, NULL, tab);
		    unify_trie_term(wl->table->data.variant, NULL, dep);
		    Sdprintf("  Deleting answer from table ");
		    PL_write_term(Serror, tab, 999, 0);
		    Sdprintf(" <-- ");
		    PL_write_term(Serror, dep, 999, PL_WRT_NEWLINE);
		  });

	    delete_answer(&wl->delays, answer);
	  }
	}
      }
    }

    discardBuffer(&di->delay_sets);
    discardBuffer(&di->delays);
    free(di);
  }
}


static void
answer_set_general_undefined(trie *atrie, trie_node *answer)
{ destroy_delay_info(atrie, answer, true);
  answer->data.delayinfo = DL_UNDEFINED;
}

/* - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - -
Delete the undefined answers that depend on this worklist
- - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - */

static void
delete_depending_answers(worklist *wl, TmpBuffer wlset)
{ DEBUG(MSG_TABLING_VTRIE_DEPENDENCIES,
	{ GET_LD
	  term_t t = PL_new_term_ref();
	  unify_trie_term(wl->table->data.variant, NULL, t);
	  Sdprintf("delete_depending_answers for ");
	  PL_write_term(Serror, t, 999, PL_WRT_NEWLINE);
	});

  while( !isEmptyBuffer(&wl->delays) )
  { trie_node **top = topBuffer(&wl->delays, trie_node*);
    trie_node *answer = top[-1];
    delay_info *di;

    assert(wl->depend_abolish);

    if ( DL_IS_DELAY_LIST(di=answer->data.delayinfo) )
    { trie *at = symbol_trie(word2atom(di->variant->value));
      worklist *dwl;

      if ( WL_IS_WORKLIST((dwl=at->data.worklist)) &&
	   !dwl->depend_abolish )
      { assert(dwl != wl);
	assert(dwl->table != wl->table);
	DEBUG(MSG_TABLING_VTRIE_DEPENDENCIES,
	      print_dl_dependency(wl->table, dwl->table));
	dwl->depend_abolish = true;
	addBuffer(wlset, dwl, worklist *);
      }
      answer_set_general_undefined(at, answer);
    } else
    { (void)popBufferP(&wl->delays, trie_node *);
    }
  }

  discardBuffer(&wl->delays);
  initBuffer(&wl->delays);
}


/* - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - -
destroy_depending_worklists(worklist *wl) destroys worklists that have
answers pointing to this worklist and its answers.
- - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - */

static void
destroy_depending_worklists(worklist *wl0)
{ tmp_buffer wlset;

  initBuffer(&wlset);
  wl0->depend_abolish = true;
  delete_depending_answers(wl0, &wlset);
  while( !isEmptyBuffer(&wlset) )
  { worklist *wl = popBuffer(&wlset, worklist *);

    delete_depending_answers(wl, &wlset);
    destroy_answer_trie(wl->table);
  }
  discardBuffer(&wlset);
}


static void *
destroy_delay_info_answer(trie_node *answer, void *ctx)
{ trie *atrie = ctx;

  if ( DL_IS_DELAY_LIST(answer->data.delayinfo) )
  { answer_set_general_undefined(atrie, answer);
  }

  return NULL;
}


static void
destroy_delay_info_worklist(worklist *wl)
{ map_trie_node(&wl->table->root, destroy_delay_info_answer, wl->table);
}


static delay_set *
create_delay_set(delay_info *di)
{ delay_set *ds;

  if ( di &&
       (ds=allocFromBuffer(&di->delay_sets, sizeof(*ds))) )
  { ds->offset = entriesBuffer(&di->delays, delay);
    ds->size   = 0;
    ds->active = 0;

    return ds;
  }

  return NULL;
}

static int
add_to_delay_set(delay_info *di, delay_set *ds,
		 trie *variant, trie_node *answer)
{ delay *d;

  if ( (d=allocFromBuffer(&di->delays, sizeof(*d))) )
  { d->variant = variant;
    d->answer  = answer;
    if ( variant )
      ds->active++;
    return ++ds->size;
  } else
  { return 0;
  }
}


/* - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - -
Register a conditional answer with  the   worklist  associated  with the
variant that contributes to the condition. The argument is a node in the
variant table. If this node is not associated   with  a worklist it is a
completed node and we are just propagating an undefined literal.
- - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - */

static int
add_to_wl_delays(trie *at, trie_node *answer, worklist *wla)
{ worklist *wl = at->data.worklist;

  if ( WL_IS_WORKLIST(wl) )
  { DEBUG(MSG_TABLING_SIMPLIFY,
	  { GET_LD
	    term_t t = PL_new_term_ref();
	    term_t v = PL_new_term_ref();
	    term_t vt = PL_new_term_ref();
	    unify_trie_term(at->data.variant, NULL, t);
	    unify_trie_term(answer, NULL, v);
	    unify_trie_term(wla->table->data.variant, NULL, vt);
	    Sdprintf("Adding propagation to worklist for ");
	    PL_write_term(Serror, t, 999, 0);
	    Sdprintf(" to answer ");
	    PL_write_term(Serror, v, 999, 0);
	    Sdprintf(" of table ");
	    PL_write_term(Serror, vt, 999, PL_WRT_NEWLINE);
	  });
    addBuffer(&wl->delays, answer, trie_node *);
  } else
  { /* see '$tbl_table_complete_all'/3 */
    DEBUG(MSG_TABLING_VTRIE_DEPENDENCIES,
	  print_dl_dependency(wla->table, at));
    assert(0);
  }

  return true;
}


static void
add_to_wl_pos_undefined(worklist *wl, trie_node *answer)
{ addBuffer(&wl->pos_undefined, answer, trie_node *);
}


/* - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - -
Simplify a delay set after adding ds. This  pops the new delay set if it
is a duplicate.
- - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - */

static int
equal_delay(const delay *a, const delay *b)
{ return ( a->variant == b->variant &&
	   a->answer  == b->answer );
}

static int
equal_delay_set(const delay *delays, const delay_set *a, const delay_set *b)
{ if ( a->size == b->size )
  { unsigned int ia = a->offset;
    unsigned int ib = b->offset;
    unsigned int ea = a->offset + a->size;

    for( ; ia < ea; ia++, ib++)
    { if ( !equal_delay(&delays[ia], &delays[ib]) )
	return false;
    }

    return true;
  }

  return false;
}


static int
simplify_delay_set(delay_info *di, delay_set *ds)
{ delay     *delays = baseBuffer(&di->delays, delay);
  delay_set *base   = baseBuffer(&di->delay_sets, delay_set);

  for(; base < ds; base++)
  { if ( equal_delay_set(delays, base, ds) )
    { seekBuffer(&di->delays, ds->offset, delay);
      popBufferP(&di->delay_sets, delay_set);
      return true;
    }
  }

  return false;
}


#define word_to_answer(w) LDFUNC(word_to_answer, w)
static inline trie_node *
word_to_answer(DECL_LD word w)
{ assert(isTaggedInt(w));

  return intToPointer((uintptr_t)valInt(w));
}


/* - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - -
The delay list (`delays`) is a  list   of  delayed positive and negative
literals:

  - Negative literal ---> answer-trie ptr
  - Positive literal ---> answer-trie ptr + answer-node ptr

TBD: If we make an answer unconditional,  should we propagate this? Note
that the worklists still  point  to   this  answer.  That should trigger
propagation?

FIXME: delete variable sharing record
- - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - */

typedef enum
{ UDL_FALSE = 0,
  UDL_TRUE,
  UDL_COMPLETE
} udl_status;

#define update_delay_list(wl, answer, skel, delays) LDFUNC(update_delay_list, wl, answer, skel, delays)
static int
update_delay_list(DECL_LD worklist *wl, trie_node *answer,
		  term_t skel, term_t delays)
{ Word ldlp;
  Word gdlp;

retry:
  deRef2(valTermRef(LD->tabling.delay_list), gdlp);
  gdlp = argTermP(*gdlp, 0);
  deRef(gdlp);
  deRef2(valTermRef(delays), ldlp);

  if ( isNil(*ldlp) && isNil(*gdlp) )
  { delay_info *di;

    if ( (di=answer->data.delayinfo) )
    { destroy_delay_info(wl->table, answer, true);
      answer->data.delayinfo = NULL;
      wl->undefined--;
      DEBUG(MSG_TABLING_SIMPLIFY,
	    Sdprintf("Unconditional answer after conditional\n"));
      simplify_answer(wl, answer, true);
    }
					/* Incremental tabling */
    if ( wl->table->data.IDG && wl->table->data.IDG->reevaluating )
    { if ( isoff(answer, TN_IDG_UNCONDITIONAL) )
	simplify_answer(wl, answer, true);
    }

    DEBUG(TABLING_NO_EARLY_COMPLETION,
	  return UDL_TRUE);

    if ( wl->ground )				/* early completion */
      return UDL_COMPLETE;
    return UDL_TRUE;
  } else
  { delay_info *di = answer_delay_info(wl, answer, true);
    delay_set  *ds = create_delay_set(di);
    size_t count;
    Word tail;

    count = skip_list(ldlp, &tail);
    if ( !isNil(*tail) )
      return PL_type_error("delay_list", delays);
    count += skip_list(gdlp, &tail);
    if ( !isNil(*tail) )
      return PL_type_error("delay_list", LD->tabling.delay_list);

    if ( !hasGlobalSpace(count+2) )
    { int rc;

      if ( (rc = ensureGlobalSpace(count+2, ALLOW_GC)) != true )
	return raiseStackOverflow(rc);
      goto retry;
    }

    if ( ds )
    { int pass = 0;
      Word dlp;
      Word   tshare = NULL;
      size_t nshare = 0;

      for(pass = 0; pass <= 1; pass++)
      {	dlp = pass ? ldlp : gdlp;

	for(; !isNil(*dlp); dlp = TailList(dlp))
	{ Word h;
	  trie *at;
	  trie_node *an;

	  deRef(dlp);
	  if ( !isList(*dlp) )
	  { PL_type_error("list", delays);
	    return UDL_FALSE;
	  }

	  h = HeadList(dlp);
	  deRef(h);
	  if ( isAtom(*h) )		/* Answer trie symbol */
	  { if ( (at=symbol_trie(word2atom(*h))) )
	    { an = NULL;
	    } else			/* deleted trie or 'undefined' */
	    { undef:
	      destroy_delay_info(wl->table, answer, true);
	      answer->data.delayinfo = DL_UNDEFINED;
	      return UDL_TRUE;
	    }
	  } else if ( isTerm(*h) )
	  { Functor f = valueTerm(*h);
	    Word p;

	    if ( f->definition == FUNCTOR_plus2 )
	    { deRef2(&f->arguments[0], p);
	      assert(isAtom(*p));
	      if ( !(at=symbol_trie(word2atom(*p))) )
	      { goto undef;
	      }
	      deRef2(&f->arguments[1], p);
	      if ( isInteger(*p) )
	      { an = word_to_answer(*p);
		assert(is_ground_trie_node(an));
	      } else
	      { int rc;

		/* ground() returns first var */
		if ( ground(p) != NULL )
		{ if ( !tshare )
		  { tshare = allocGlobalNoShift(3);
		    assert(tshare);
		    tshare[1] = linkValI(valTermRef(skel));
		    tshare[2] = *p;
		    nshare = 1;
		  } else
		  { Word s = allocGlobalNoShift(1);
		    assert(s);
		    s[0] = *p;
		    nshare++;
		  }
		}

		if ( ison(at, TRIE_ISMAP) )	/* answer subsumption */
		{ Word rp;
		  trie_node *root;

		  assert(hasFunctor(*p, FUNCTOR_divide2));
		  rp = argTermP(*p, 0);
		  rc = trie_lookup(at, NULL, &root, rp+0, true, NULL);
		  if ( rc == true )
		  { rc = trie_lookup(at, root, &an, rp+1, true, NULL);
		  }
		} else
		{ rc = trie_lookup(at, NULL, &an, p, true, NULL);
		}

		if ( rc == true )
		{ // TBD: can we immediately simplify if this already has a value?
		  DEBUG(MSG_TABLING_DELAY_VAR,
			print_delay("Waiting for instantiated",
				    at->data.variant, an));
		  // TBD: at->data.worklist?
		  add_to_wl_pos_undefined(wl, an);
		} else
		{ return trie_trie_error(rc, at);
		}
	      }
	    } else
	    { PL_type_error("delay_list", delays);
	      return UDL_FALSE;
	    }
	  } else
	  { PL_type_error("delay_list", delays);
	    return UDL_FALSE;
	  }

	  assert(at->magic == TRIE_MAGIC);

	  if ( !add_to_delay_set(di, ds, at, an) )
	    goto nomem;
	} /*for list*/
      } /*for pass*/

      if ( tshare )
      { word w = consPtr(tshare, TAG_COMPOUND|STG_GLOBAL);
	record_t r;

	tshare[0] = PL_new_functor(ATOM_v, nshare+1);
	r = PL_record(pushWordAsTermRef(&w));
	popTermRef();
	if ( r )
	{ if ( !add_to_delay_set(di, ds, NULL, REC_DELAY(r)) )
	    goto nomem;
	  di->has_share_records = true;
	} else
	{ return UDL_FALSE;
	}
      }

      if ( tshare || !simplify_delay_set(di, ds) )
      { delay *d = baseBuffer(&di->delays, delay);
	unsigned int i, e = ds->offset+ds->size;

	for(i=ds->offset; i<e; i++)
	{ if ( d[i].variant )
	  { if ( !add_to_wl_delays(d[i].variant, answer, wl) )
	      return UDL_FALSE;
	  }
	}
      }

      return UDL_TRUE;
    }

  nomem:
    PL_resource_error("memory");
    return UDL_FALSE;
  }
}


static void
delay_sets(delay_info *di, delay_set **base, delay_set **top)
{ *base = baseBuffer(&di->delay_sets, delay_set);
  *top  = topBuffer(&di->delay_sets, delay_set);
}

static void
get_delay_set(delay_info *di, delay_set *set, delay **base, delay **top)
{ *base = baseBuffer(&di->delays, delay) + set->offset;
  *top  = (*base) + set->size;
}


term_t
init_delay_list(void)
{ GET_LD
  term_t t = PL_new_term_ref();
  Word p = allocGlobal(2);

  p[0] = FUNCTOR_minus1;
  p[1] = ATOM_nil;

  *valTermRef(t) = consPtr(p, TAG_COMPOUND|STG_GLOBAL);

  return t;
}


bool
PL_get_delay_list(term_t t)
{ GET_LD

  term_t dl = LD->tabling.delay_list;

  if ( t )
  { _PL_get_arg(1, dl, t);
    return !PL_get_nil(t);
  } else
  { Word p = valTermRef(dl);
    deRef(p);

    return argTerm(*p,0) != ATOM_nil ;
  }
}


static
PRED_IMPL("$tbl_delay_list", 1, tbl_delay_list, 0)
{ PRED_LD;
  term_t dl = LD->tabling.delay_list;
  term_t a = PL_new_term_ref();

  return ( _PL_get_arg(1, dl, a) &&
	   PL_unify(A1, a) );
}

static
PRED_IMPL("$tbl_set_delay_list", 1, tbl_set_delay_list, 0)
{ PRED_LD;
  term_t dl = LD->tabling.delay_list;
  Word p;

  if ( !hasGlobalSpace(0) )
  { int rc;

    if ( (rc=ensureGlobalSpace(0, ALLOW_GC)) != true )
      return raiseStackOverflow(rc);
  }

  p = valTermRef(dl);
  if ( isTerm(*p) )
  { p = argTermP(*p, 0);

    TrailAssignment(p);
    unify_vp(p, valTermRef(A1));
  }

  return true;
}

#define push_delay_list(p) LDFUNC(push_delay_list, p)
static void
push_delay_list(DECL_LD Word p)
{ Word dl = valTermRef(LD->tabling.delay_list);

  assert(isTerm(*dl));
  dl = argTermP(*dl, 0);
  p[2] = *dl;
  TrailAssignment(dl);
  *dl = consPtr(p, TAG_COMPOUND|STG_GLOBAL);
}

/* Push a positive delay node.  If the answer is ground this is a
 * term atrie+answer, else it is a term atrie+wrapper.
 */

#define delay_to_data(answer, wrapper) LDFUNC(delay_to_data, answer, wrapper)
static word
delay_to_data(DECL_LD trie_node *answer, Word wrapper)
{ if ( unlikely(answer == NULL) )
  { return consInt(0);
  } else if ( is_ground_trie_node(answer) )
  {
#if SIZEOF_WORD == 8
    word rc = consInt(pointerToInt(answer));
    DEBUG(0, assert(intToPointer((uintptr_t)valInt(rc)) == answer));
    return rc;
#else
    word rc;
    intptr_t i = pointerToInt(answer);

    rc = consInt(i);
    if ( i == valInt(rc) )
    { return rc;
    } else
    { int rcp = put_int64(&rc, i, 0);
      return rcp == true ? rc : 0;
    }
#endif
  } else
  { return linkValI(wrapper);
  }
}


void
tbl_push_delay(DECL_LD atom_t atrie, Word wrapper, trie_node *answer)
{ Word p;
  word p5 = delay_to_data(answer, wrapper);

  assert(p5);

  if ( (p = allocGlobalNoShift(6)) )
  { p[0] = FUNCTOR_dot2;
    p[1] = consPtr(&p[3], TAG_COMPOUND|STG_GLOBAL);
    p[3] = FUNCTOR_plus2;
    p[4] = atrie;
    p[5] = p5;

    push_delay_list(p);
  } else
  { assert(0);
  }
}


/** '$tbl_add_global_delays'(+Delays0, -Delays) is det.
 *
 *  Delays is the result of appending the  global delay list to Delays0.
 *  This is a highly time  critical   operation  and might eventually be
 *  merged into '$tbl_wkl_add_answer'/4 and '$tbl_wkl_add_suspension'/2.
 */

static
PRED_IMPL("$tbl_add_global_delays", 2, tbl_add_global_delays, 0)
{ PRED_LD
  term_t dl = PL_new_term_ref();

  _PL_get_arg(1, LD->tabling.delay_list, dl);

  if ( PL_get_nil(dl) )
  { return PL_unify(A1, A2);
  } else if ( PL_get_nil(A1) )
  { return PL_unify(A2, dl);
  } else
  { intptr_t len;
    Word tailp;
    Word dlp, p;
    word l;

    len = skip_list(valTermRef(dl), &tailp);
    assert(isNil(*tailp));

    if ( !(p=allocGlobal(3*len)) )
      return false;
    l = consPtr(p, TAG_COMPOUND|STG_GLOBAL);

    dlp = valTermRef(dl);
    deRef(dlp);

    for(;;)
    { *p++ = FUNCTOR_dot2;
      *p++ = linkValI(HeadList(dlp));
      dlp = TailList(dlp);
      deRef(dlp);
      if ( isNil(*dlp) )
      { *p = linkValI(valTermRef(A1));
	return PL_unify_atomic(A2, l);
      }
      *p   = consPtr(&p[1], TAG_COMPOUND|STG_GLOBAL);
      p++;
    }
  }
}

		 /*******************************
		 *	  SIMPLIFICATION	*
		 *******************************/

static int	answer_completion(tbl_component *scc);

typedef struct propagate
{ worklist  *worklist;
  trie_node *answer;
  int	     result;
} propagate;

typedef struct agenda
{ size_t	done;
  tmp_buffer	buffer;
} spf_agenda;

static void
init_spf_agenda(spf_agenda *a)
{ a->done = 0;
  initBuffer(&a->buffer);
}

static void
exit_spf_agenda(spf_agenda *a)
{ discardBuffer(&a->buffer);
}

static int
push_propagate(spf_agenda *a, worklist *wl, trie_node *answer, int result)
{ propagate *p = allocFromBuffer(&a->buffer, sizeof(*p));

  p->worklist = wl;
  p->answer   = answer;
  p->result   = result;

  return true;
}

static propagate *
pop_propagate(spf_agenda *a)
{ if ( isEmptyBuffer(&a->buffer) )
    return NULL;

  return popBufferP(&a->buffer, propagate);
}


static int propagate_result(spf_agenda *agenda,
			    worklist *wl, trie_node *answer, int result);
#ifdef O_DEBUG
static void print_delay(const char *msg, trie_node *variant, trie_node *answer);
#endif

static int
make_answer_unconditional(spf_agenda *agenda, trie_node *answer)
{ delay_info *di = answer->data.delayinfo;

  if ( DL_IS_DELAY_LIST(di) )
  { trie *at = symbol_trie(word2atom(di->variant->value));
    worklist *wl = at->data.worklist;
    assert(wl->magic == WORKLIST_MAGIC);

    DEBUG(MSG_TABLING_SIMPLIFY,
	  print_delay("   Making answer unconditional", di->variant, answer));

    destroy_delay_info(at, answer, true);
    agenda->done++;
    wl->undefined--;

    if ( !isEmptyBuffer(&wl->delays) )
      push_propagate(agenda, wl, answer, true);
  } else
  { assert(0);
  }

  return true;
}


static int
remove_conditional_answer(spf_agenda *agenda, trie_node *answer)
{ delay_info *di = answer->data.delayinfo;

  if ( DL_IS_DELAY_LIST(di) )
  { trie *at = symbol_trie(word2atom(di->variant->value));
    worklist *wl = at->data.worklist;

    assert(wl->magic == WORKLIST_MAGIC);

    DEBUG(MSG_TABLING_SIMPLIFY,
	  print_delay("    Removing conditional answer", di->variant, answer));

    destroy_delay_info(at, answer, true);
    trie_delete(at, answer, true);		/* cannot prune as may be */
    agenda->done++;				/* in worklist delay lists */
    wl->undefined--;

    if ( !isEmptyBuffer(&wl->delays) )
      push_propagate(agenda, wl, answer, false);
  }

  return true;
}



static void
answer_delay_sets(delay_info *di, delay_set **base, delay_set **top)
{ *base = baseBuffer(&di->delay_sets, delay_set);
  *top  = topBuffer(&di->delay_sets, delay_set);
}


/* - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - -
Propagate a result in worklist wl. For  negative nodes `answer` is NULL.
The `result` indicates whether the  answer   is  satisfied (true) or not
(false). If an answer is satisfied it is removed from the delay list and
if  the  resulting  delay  list  becomes    empty  the  answer  is  made
unconditional. Otherwise the delay list can   no longer become satisfied
and we remove the delay list. If this was the last delay list the answer
is definitely invalid and can be removed from the answer trie.

Answer to propagate is <wl,panswer> with truth result.
This answer is propagate to `answer`
- - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - */

static int
propagate_to_answer(spf_agenda *agenda, worklist *wl,
		    trie_node *panswer, int result, trie_node *answer)
{ delay_info *di;
  trie *variant = wl->table;
  int found = false;

  DEBUG(MSG_TABLING_SIMPLIFY, print_answer("  to", answer));

  if ( (di=answer_delay_info(NULL, answer, false)) )
  { delay_set *ds, *dz;
    delay *db = baseBuffer(&di->delays, delay);

    for(answer_delay_sets(di, &ds, &dz); ds < dz; ds++)
    { unsigned o;
      unsigned oe = ds->offset+ds->size;

      for(o=ds->offset; o<oe; o++)
      { delay *d = &db[o];

	if ( d->variant == variant )
	{ if ( d->answer == panswer || d->answer == NULL )
	  { int res;

	    DEBUG(MSG_TABLING_SIMPLIFY,
		  Sdprintf("   found (SCC=%zd, simplifications = %zd)\n",
			   pointerToInt(wl->component),
			   wl->component->simplifications));

	    if ( d->answer == NULL )
	    { if ( result == false &&
		   (wl->has_answers || wl->undefined) )
		continue;
	      res = !result;
	    } else
	    { res = result;
	    }

	    found = true;
	    wl->component->simplifications++;

	    if ( res )			/* remove member from conjunction */
	    { d->variant = DV_DELETED;
	      if ( --ds->active == 0 )
	      { make_answer_unconditional(agenda, answer);
		return found;
	      }
	    } else			/* remove the conjunction */
	    { memmove(ds, ds+1, sizeof(*ds)*(dz-ds-1));
	      (void)popBufferP(&di->delay_sets, delay_set);
	      ds--;			/* compensate for(;;ds++) */
	      dz--;
	      break;
	    }
	  }
	}
      }

      if ( isEmptyBuffer(&di->delay_sets) )
      { remove_conditional_answer(agenda, answer);
	return found;
      }
    }
  }

  if ( found )
    DEBUG(MSG_TABLING_SIMPLIFY, print_answer("  now", answer));

  return found;
}


static int
propagate_result(spf_agenda *agenda,
		 worklist *wl, trie_node *panswer, int result)
{ DEBUG(MSG_TABLING_SIMPLIFY,
	{ print_delay(result ? "Propagating true" : "Propagating false",
		      wl->table->data.variant, panswer);
	  Sdprintf("  %zd dependent answers\n",
		   entriesBuffer(&wl->delays, trie_node*));
	});

  while( !isEmptyBuffer(&wl->delays) )
  { trie_node *answer = popBuffer(&wl->delays, trie_node*);

    propagate_to_answer(agenda, wl, panswer, result, answer);
  }

  return true;
}


static int
simplify_answer(worklist *wl, trie_node *answer, int truth)
{ spf_agenda agenda;
  propagate *p;

  init_spf_agenda(&agenda);
  push_propagate(&agenda, wl, answer, truth);
  while( (p=pop_propagate(&agenda)) )
    propagate_result(&agenda, p->worklist, p->answer, p->result);
  exit_spf_agenda(&agenda);

  return true;
}


static int
simplify_component(tbl_component *scc)
{ spf_agenda agenda;
  propagate *p;
  worklist **wlp0 = baseBuffer(&scc->created_worklists->members, worklist*);
  worklist **top  = topBuffer(&scc->created_worklists->members, worklist*);
  worklist **wlp;
  int undefined, pass;
#ifndef O_AC_EAGER
  size_t simplified0 = scc->simplifications;
#endif

  DEBUG(MSG_TABLING_SIMPLIFY,
	{ GET_LD
	  term_t t = PL_new_term_ref();
	  unify_trie_term(scc->leader->data.variant, NULL, t);
	  Sdprintf("Simplifying SCC %zd; leader = ", pointerToInt(scc));
	  PL_write_term(Serror, t, 999, PL_WRT_NEWLINE);
	});

  init_spf_agenda(&agenda);

  for(pass=0; ;pass++)
  { int count = 0;

    undefined = 0;

    for(wlp = wlp0; wlp < top; wlp++)
    { worklist *wl = *wlp;

      if ( pass == 0 )
	clean_worklist(wl);

      if ( wl->negative &&
	   wl->neg_delayed &&
	   wl->table->value_count == 0 &&
	   !isEmptyBuffer(&wl->delays) )
      { DEBUG(MSG_TABLING_SIMPLIFY,
	      { GET_LD
		term_t t = PL_new_term_ref();
		unify_trie_term(wl->table->data.variant, NULL, t);
		Sdprintf("No conditional answers for %zd: ", pointerToInt(wl));
		PL_write_term(Serror, t, 999, PL_WRT_NEWLINE);
	      });

	count++;
	push_propagate(&agenda, wl, NULL, false);
	while( (p=pop_propagate(&agenda)) )
	  propagate_result(&agenda, p->worklist, p->answer, p->result);
      }

      if ( !isEmptyBuffer(&wl->pos_undefined) )
      { trie_node **bn = baseBuffer(&wl->pos_undefined, trie_node *);
	trie_node **en = topBuffer(&wl->pos_undefined, trie_node *);
	trie_node **on = bn;

	for(; bn < en; bn++)
	{ trie_node *an = *bn;

	  if ( !answer_is_conditional(an) )
	  { DEBUG(MSG_TABLING_SIMPLIFY,
		  print_answer("Propagating now unconditional answer", an));
	    count++;
	    push_propagate(&agenda, wl, an, an->value != 0);
	    while( (p=pop_propagate(&agenda)) )
	      propagate_result(&agenda, p->worklist, p->answer, p->result);
	  } else
	  { *on++ = an;
	  }
	}
	wl->pos_undefined.top = (char*)on;
      }

      if ( wl->undefined )
	undefined++;
    }

    if ( count == 0 || undefined == 0 )
      break;
  }

  exit_spf_agenda(&agenda);

#ifndef O_AC_EAGER
  if ( (simplified0 != scc->simplifications) )
  { size_t cnt = scc->simplifications - simplified0 ;
    tbl_component *c;

    for(c = scc->parent; c; c = c->parent)
      c->simplifications += cnt;
  }
#endif

  /* DSW: there cannot be any "uncovering" of a positive loop if there
   * was no simplification
   */

  DEBUG(MSG_TABLING_SIMPLIFY,
	Sdprintf("Simplified SCC %zd; undefined = %d; simplifications: %zd\n",
		 pointerToInt(scc), undefined, scc->simplifications));

  if ( undefined && scc->simplifications )
    return answer_completion(scc);
  else
    return true;
}

#ifdef O_DEBUG
static void
print_dl_dependency(trie *from, trie *to)
{ GET_LD
  term_t From = PL_new_term_ref();
  term_t To   = PL_new_term_ref();

  unify_trie_term(from->data.variant, NULL, From);
  unify_trie_term(to->data.variant, NULL, To);
  Sdprintf("Delay list dep from %p (", from);
  PL_write_term(Serror, From, 999, 0);
  Sdprintf(") -> %p (", to);
  PL_write_term(Serror, To, 999, 0);
  Sdprintf(")\n");
}
#endif

		 /*******************************
		 *	ANSWER COMPLETION	*
		 *******************************/

/* - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - -
The role of answer completion  is  to   remove  positive  loops from the
remaining delay lists. We do   this by calling answer_completion(+ATrie)
in  boot/tabling.pl.  This  predicate  uses  recursive  tabling  on  the
residual program that involves the given  ATrie and removing all answers
deduced as false and marking those deduced as true as `answer_completed`

We search for a candidate worklist as one that is undefined (e.g., has a
residual program) and has at  least  one   depending  answer  that has a
positive delay element because a positive loop needs to include at least
one positive dependency.
- - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - */

#define call_answer_completion(atrie) LDFUNC(call_answer_completion, atrie)
static int
call_answer_completion(DECL_LD trie *atrie)
{ fid_t fid;

  if ( (fid = PL_open_foreign_frame()) )
  { predicate_t pred;
    term_t av = PL_new_term_refs(2);
    int rc;
    tbl_component *scc_old = LD->tabling.component;
    int hsc = LD->tabling.has_scheduling_component;

    pred = _PL_predicate("answer_completion", 2, "$tabling",
			 &GD->procedures.answer_completion2);

    DEBUG(MSG_TABLING_AC,
	  { term_t t = PL_new_term_ref();
	    unify_trie_term(atrie->data.variant, NULL, t);
	    Sdprintf("Calling answer completion for: ");
	    PL_write_term(Serror, t, 999, PL_WRT_NEWLINE);
	  });

    LD->tabling.component = NULL;
    LD->tabling.has_scheduling_component = false;
    LD->tabling.in_answer_completion = true;
    rc = ( PL_put_atom(av+0, atrie->symbol) &&
	   unify_skeleton(atrie, 0, av+1) &&
	   PL_call_predicate(NULL, PL_Q_PASS_EXCEPTION, pred, av) );
    LD->tabling.in_answer_completion = false;
    LD->tabling.has_scheduling_component = hsc;
    LD->tabling.component = scc_old;

    PL_close_foreign_frame(fid);
    return rc;
  } else
    return false;				/* stack overflow */
}


/* - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - -
A variant can only be subject to answer   completion  if it has at least
one answer that  is  undefined  and   has  a  condition  containing only
positive delay elements.
- - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - */

#ifdef O_AC_EAGER
static int
has_positive_dl(trie_node *n)
{ delay_info *di;

  if ( n->value && DL_IS_DELAY_LIST(di=n->data.delayinfo) )
  { delay_set *ds, *dz;
    delay *db = baseBuffer(&di->delays, delay);

    for(answer_delay_sets(di, &ds, &dz); ds < dz; ds++)
    { unsigned o;
      unsigned oe = ds->offset+ds->size;

      for(o=ds->offset; o<oe; o++)
      { delay *d = &db[o];

	if ( d->variant && d->variant != DV_DELETED )
	{ if ( d->answer )
	    return true;
	}
      }
    }
  }

  return false;
}

static int
is_ac_candidate_wl(worklist *wl)
{ if ( wl->undefined && !wl->answer_completed &&
       !isEmptyBuffer(&wl->delays) )
  { trie_node **n = baseBuffer(&wl->delays, trie_node*);
    trie_node **z =  topBuffer(&wl->delays, trie_node*);

    for( ; n < z; n++)
    { if ( has_positive_dl(*n) )
	return true;
    }
  }

  return false;
}
#endif /*O_AC_EAGER*/


static int
answer_completion(tbl_component *scc)
{ GET_LD

#ifdef O_DEBUG
  if ( DEBUGGING(TABLING_NO_AC) )
    return true;
#endif

  if ( LD->tabling.in_answer_completion )
    return true;			/* not recursive! */

#ifdef O_AC_EAGER
  worklist **wlp = baseBuffer(&scc->created_worklists->members, worklist*);
  worklist **top = topBuffer(&scc->created_worklists->members, worklist*);

  for(; wlp < top; wlp++)
  { worklist *wl = *wlp;

    if ( is_ac_candidate_wl(wl) )
    { if ( !call_answer_completion(wl->table) )
	return false;
    }
  }

  return true;
#else
  return call_answer_completion(scc->leader);
#endif /*O_AC_EAGER*/
}

/** '$tbl_force_truth_value'(+AnswerNode, +Value, -Count)
 *
 * Force AnswerNode to have truth value Value.  Count returns the
 * number of answer nodes that have been changed, which may be more
 * than one due to propagation.
 */

static
PRED_IMPL("$tbl_force_truth_value", 3, tbl_force_truth_value, 0)
{ PRED_LD
  void *ptr;
  int truth;
  int rc = false;

  if ( PL_get_pointer_ex(A1, &ptr) &&
       PL_get_bool_ex(A2, &truth) )
  { trie_node *answer = ptr;
    delay_info *di = answer->data.delayinfo;
    spf_agenda agenda;
    propagate *p;

    init_spf_agenda(&agenda);

    if ( DL_IS_DELAY_LIST(di) )
    { trie *at = symbol_trie(word2atom(di->variant->value));
      worklist *wl = at->data.worklist;

      DEBUG(MSG_TABLING_AC,
	    { term_t v = PL_new_term_ref();
	      term_t a = PL_new_term_ref();

	      unify_trie_term(at->data.variant, NULL, v);
	      unify_trie_term(answer, NULL, a);
	      Sdprintf("Forcing answer ");
	      PL_write_term(Serror, a, 999, 0);
	      Sdprintf(" for ");
	      PL_write_term(Serror, v, 999, 0);
	      Sdprintf(" to false\n");
	    });

      if ( WL_IS_WORKLIST(wl) )
      { if ( truth )
	  rc = make_answer_unconditional(&agenda, answer);
	else
	  rc = remove_conditional_answer(&agenda, answer);
      } else
      { rc = PL_permission_error("force_truth_value", "answer", A1);
      }
    } else					/* answer is not conditional */
    { if ( !truth )
      { trie *at = get_trie_from_node(answer);

	trie_delete(at, answer, false);		/* TBD: propagate? */
      }
      rc = true;
    }

    while( rc && (p=pop_propagate(&agenda)) )
      rc = propagate_result(&agenda, p->worklist, p->answer, p->result);

    rc = rc && PL_unify_integer(A3, agenda.done);

    exit_spf_agenda(&agenda);
  }

  return rc;
}


static
PRED_IMPL("$tbl_set_answer_completed", 1, tbl_set_answer_completed, 0)
{ trie *trie;

  if ( get_trie(A1, &trie) )
  { worklist *wl;

    if ( WL_IS_WORKLIST((wl=trie->data.worklist)) )
    { wl->answer_completed = true;

      return true;
    }

    if ( ison(trie, TRIE_COMPLETE) )
      return true;

    return PL_permission_error("set_answer_complete", "trie", A1);
  }

  return false;
}

static
PRED_IMPL("$tbl_is_answer_completed", 1, tbl_is_answer_completed, 0)
{ trie *trie;

  if ( get_trie(A1, &trie) )
  { worklist *wl;

    if ( WL_IS_WORKLIST((wl=trie->data.worklist)) )
      return wl->answer_completed;

    return !!ison(trie, TRIE_COMPLETE);
  }

  return false;
}


#ifdef O_DEBUG
static void
print_delay(const char *msg, trie_node *variant, trie_node *answer)
{ GET_LD
  term_t t = PL_new_term_ref();

  unify_trie_term(variant, NULL, t);
  Sdprintf("%s: %s", msg, answer ? "" : "~");
  PL_write_term(Serror, t, 999, answer ? 0 : PL_WRT_NEWLINE);
  if ( answer )
  { PL_put_variable(t);
    unify_trie_term(answer, NULL, t);
    Sdprintf(", answer: ");
    PL_write_term(Serror, t, 999, PL_WRT_NEWLINE);
  }
}

static void
print_answer(const char *msg, trie_node *answer)
{ GET_LD
  trie *at = get_trie_from_node(answer);
  term_t t = PL_new_term_ref();

  unify_trie_term(at->data.variant, NULL, t);
  Sdprintf("[Thread %d] %s: variant ", PL_thread_self(), msg);
  PL_write_term(Serror, t, 999, 0);
  PL_put_variable(t);
  unify_trie_term(answer, NULL, t);
  Sdprintf(", answer: ");
  PL_write_term(Serror, t, 999, 0);
  if ( !answer->value )
    Sdprintf(" (NULL)");
  if ( answer_is_conditional(answer) )
  { put_delay_info(t, answer);
    Sdprintf(" (IF ");
    PL_write_term(Serror, t, 999, 0);
    Sdprintf(")\n");
  } else
    Sdprintf("\n");
}

static void
print_answer_table(trie *atrie, const char *msg, ...)
{ GET_LD
  va_list args;
  term_t t = PL_new_term_ref();

  va_start(args, msg);
  unify_trie_term(atrie->data.variant, NULL, t);
  if ( msg )
  { if ( ison(atrie, TRIE_ISSHARED) )
      Sdprintf("Thread [%d]: ", PL_thread_self());

    Svdprintf(msg, args);
    Sdprintf(": <trie>(%p) for ", atrie);
  }
  va_end(args);
  PL_write_term(Serror, t, 999, PL_WRT_NEWLINE);
}

#endif

		 /*******************************
		 *	      SUSPEND		*
		 *******************************/

void
save_tabling_status(tbl_status *state)
{ GET_LD

  state->scc = LD->tabling.component;
  state->hsc = LD->tabling.has_scheduling_component;
  state->iac = LD->tabling.in_answer_completion;
  state->iap = LD->tabling.in_assert_propagation;

  LD->tabling.component                = NULL;
  LD->tabling.has_scheduling_component = false;
  LD->tabling.in_answer_completion     = false;
  LD->tabling.in_assert_propagation    = false;
}


void
restore_tabling_status(tbl_status *state)
{ GET_LD

  LD->tabling.component                = state->scc;
  LD->tabling.has_scheduling_component = state->hsc;
  LD->tabling.in_answer_completion     = state->iac;
  LD->tabling.in_assert_propagation    = state->iap;
}



		 /*******************************
		 *     (THREAD) VARIANT TABLE	*
		 *******************************/

static void release_variant_table_node(trie *trie, trie_node *node);

/* Get the variant  table.  If `shared` is `true`, this  is for shared
 * tabling.  Otherwise  it is for  (thread) local tabling.   This trie
 * maps call variants to answer tables.
 */

#define variant_table(shared) LDFUNC(variant_table, shared)

static trie *
variant_table(DECL_LD bool shared)
{ trie **tp;
  alloc_pool *pool;

#ifdef O_PLMT
  if ( shared )
  { tp   = &GD->tabling.variant_table;
    if ( !(pool = GD->tabling.node_pool) )
    { if ( (pool = new_alloc_pool("shared_table_space",
				  GD->options.sharedTableSpace)) )
      { if ( !COMPARE_AND_SWAP_PTR(&GD->tabling.node_pool, NULL, pool) )
	{ free_alloc_pool(pool);
	  pool = GD->tabling.node_pool;
	}
      } else
      { return NULL;
      }
    }
  } else
#endif
  { tp   = &LD->tabling.variant_table;
    if ( !(pool = LD->tabling.node_pool) )
    { pool = LD->tabling.node_pool = new_alloc_pool("private_table_space",
						    GD->options.tableSpace);
      if ( !pool )
	return NULL;
    }
  }

  if ( *tp == NULL )
  { trie *t;

    if ( (t = trie_create(pool)) )
    { atom_t symb;

      t->release_node = release_variant_table_node;
      symb = trie_symbol(t);

      if ( COMPARE_AND_SWAP_PTR(tp, NULL, t) )
      { if ( shared )
	{ set(t, TRIE_ISSHARED);
	  acquire_trie(t);			/* bit misuse */
	}
      } else
      { PL_unregister_atom(symb);		/* destroyed by atom-GC */
      }
    }
  }

  return *tp;
}


static void
reset_answer_table(trie *atrie, int cleanup)
{ worklist *wl;
  idg_node *n;

  if ( WL_IS_WORKLIST(wl=atrie->data.worklist) )
  { if ( !isEmptyBuffer(&wl->delays) && !cleanup )
      destroy_depending_worklists(wl);
    if ( wl->undefined )
      destroy_delay_info_worklist(wl);
    atrie->data.worklist = NULL;
    clear(atrie, TRIE_ABOLISH_ON_COMPLETE);
    free_worklist(wl);
  } else if ( wl )
  { atrie->data.worklist = NULL;		/* make fresh again */
  }
  clear(atrie, TRIE_COMPLETE);

  if ( (n=atrie->data.IDG) )
  { if ( ison(atrie, TRIE_ISSHARED) && GD->halt.cleaning != CLN_DATA )
    { idg_reset(n);
    } else
    { atrie->data.IDG = NULL;
      idg_destroy(n);
    }
  }

  if ( ison(atrie, TRIE_ISTRACKED) )
    tt_abolish_table(atrie);

  trie_empty(atrie);
}


static void
release_variant_table_node(trie *variant_table, trie_node *node)
{ (void)variant_table;

  if ( node->value )
  { trie *atrie = symbol_trie(word2atom(node->value));

    reset_answer_table(atrie, variant_table->magic == TRIE_CMAGIC);
    assert(atrie->data.variant == node);
    atrie->data.variant = NULL;
  }
}


static bool
is_variant_trie(trie *trie)
{ return trie->release_node == release_variant_table_node;
}


static void
clear_variant_table(trie **vtriep)
{ trie *vtrie;

  if ( (vtrie=*vtriep) )
  { vtrie->magic = TRIE_CMAGIC;
    if ( ison(vtrie, TRIE_ISSHARED) )
      release_trie(vtrie);			/* acquired in variant_table() */
    trie_empty(vtrie);
    PL_unregister_atom(vtrie->symbol);
    *vtriep = NULL;
  }
}


#define VAR_SKEL_FAST 8
static functor_t fast_ret_functor[VAR_SKEL_FAST] = {0};

#define unify_trie_ret(ret, vars) LDFUNC(unify_trie_ret, ret, vars)

static size_t
trie_ret_arity(Word const *pp, Word const *ep)
{
#if O_TRIE_ATTVAR
  size_t arity = 0;

  for(Word const *ap = pp; ap<ep; ap++)
  { if ( isAttVar(**ap) )
      ap++;
    arity++;
  }

  return arity;
#else
  return ep-pp;
#endif
}

static int /* bool or *_OVERFLOW */
unify_trie_ret(DECL_LD term_t ret, TmpBuffer vars)
{ Word *pp = baseBuffer(vars, Word);
  Word *ep = topBuffer(vars, Word);
  size_t arity = trie_ret_arity(pp, ep);
  functor_t vf;

  assert(arity > 0);
  if ( arity < VAR_SKEL_FAST )
  { if ( !(vf=fast_ret_functor[arity]) )
      fast_ret_functor[arity] = vf = PL_new_functor(ATOM_ret, arity);
  } else
  { vf = PL_new_functor(ATOM_ret, arity);
  }

  assert(valueFunctor(vf));

  if ( hasGlobalSpace(arity+1) )
  { Word p = allocGlobalNoShift(arity+1);
    word w = consPtr(p, TAG_COMPOUND|STG_GLOBAL);
    *p++ = vf;

    for(; pp < ep; pp++)
    { Word ap = *pp;

      if ( isVar(*ap) )
      { *p++ = makeRefG(ap);
#if O_TRIE_ATTVAR
      } else if ( isAttVar(*ap) )
      { *p++ = makeRefG(ap);
	pp++;			/* skip attribute */
#endif
      } else			/* can this happen? */
      { *p++ = *ap;
      }
    }

    if ( PL_is_variable(ret) )
      return PL_unify_atomic(ret, w);
    else
      return unify_ptrs(valTermRef(ret), &w, ALLOW_RETCODE);
  }

  return GLOBAL_OVERFLOW;
}


static void
release_answer_node(trie *atrie, trie_node *node)
{ if ( DL_IS_DELAY_LIST(node->data.delayinfo) )
    destroy_delay_info(atrie, node, true);
}


/* - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - -
get_answer_table(+Variant, -Return, int flags)

Find the answer table for  Variant  and   its  return  template  (a term
ret/N). If `create` is true, create the table if it does not exist.

(*) We must avoid a race  with   trie_discard_clause().  As  long as the
(atom) clause reference is not garbage collected  the clause is safe. We
first check there is an atom, then push  it as a volatile atom and check
it again. If the atom is still valid it is not protected against atom-gc
by pushVolatileAtom() and will  be  unified   before  anything  else  in
'$variant_table'/5, so it remains valid.
- - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - */

#define AT_CREATE		0x0001
#define AT_MODED		0x0002	/* moded tabling: trie has values */
#define AT_SHARED		0x0004	/* find a shared table */
#define AT_PRIVATE		0x0008	/* find a private table */
#define AT_NOCLAIM		0x0010	/* Do not claim ownership */


#define AT_ABSTRACT		0x0020	/* subgoal_abstract(N) tabling */
#define AT_SCOPE_MASK (AT_SHARED|AT_PRIVATE)

#define pred_max_table_subgoal_size(def) LDFUNC(pred_max_table_subgoal_size, def)
static inline size_t
pred_max_table_subgoal_size(DECL_LD const Definition def)
{ size_t limit;

  limit = def->tabling ? def->tabling->subgoal_abstract : (size_t)-1;
  if ( limit == (size_t)-1 )
    limit = LD->tabling.restraint.max_table_subgoal_size;

  return limit;
}


#define get_answer_table(def, t, ret, clrefp, flags) LDFUNC(get_answer_table, def, t, ret, clrefp, flags)
static trie *
get_answer_table(DECL_LD Definition def, term_t t, term_t ret, atom_t *clrefp,
		 int flags)
{ trie *variants;
  trie *atrie;
  trie_node *node;
  int rc;
  Word v;
  tmp_buffer vars;
  mark m;
  bool shared;
  size_abstract sa = {.from_depth = 2, .size = (size_t)-1};

#ifdef O_PLMT
  if ( (flags & AT_SCOPE_MASK) )
  { shared = !!(flags&AT_SHARED);
  } else
  { if ( !def )					/* we should avoid these */
    { Procedure proc;

      if ( get_procedure(t, &proc, 0, GP_RESOLVE) )
      { def = proc->definition;
      } else
      { assert(0);
	return NULL;
      }
    }
    shared = def->tabling && ison(def->tabling, TP_SHARED);
  }
#else
  shared = false;
#endif

  if ( def )			/* otherwise we don't need it anyway */
    sa.size = pred_max_table_subgoal_size(def);
  variants = variant_table(shared);
  initBuffer(&vars);

retry:
  Mark(m);
  v = valTermRef(t);
  rc = trie_lookup_abstract(variants, NULL, &node, v, (flags&AT_CREATE),
			    &sa, &vars);

  if ( rc > 0 )
  { if ( rc == TRIE_ABSTRACTED )
    { atom_t action = LD->tabling.restraint.max_table_subgoal_size_action;

      DEBUG(MSG_TABLING_RESTRAINT,
	    Sdprintf("Trapped by subgoal size restraint\n"));
      if ( action == ATOM_abstract && !(flags&AT_ABSTRACT) )
	action = ATOM_error;

      if ( action != ATOM_abstract )
      { if ( tbl_pred_tripwire(def, action, ATOM_max_table_subgoal_size) )
	{ sa.size = (size_t)-1;
	  emptyBuffer(&vars, (size_t)-1);
	  goto retry;
	} else
	{ discardBuffer(&vars);
	  return NULL;
	}
      }
    }

    if ( node->value )
    { atrie = symbol_trie(word2atom(node->value));
    } else if ( (flags&AT_CREATE) )
    { atom_t symb;
#ifdef O_PLMT
      alloc_pool *pool = (shared ? GD->tabling.node_pool
				 : LD->tabling.node_pool);
#else
      alloc_pool *pool = LD->tabling.node_pool;
#endif

      if ( !(atrie = trie_create(pool)) )
	return NULL;
      set(atrie, TRIE_ISTABLE|((flags&AT_MODED) ? TRIE_ISMAP : TRIE_ISSET));
      atrie->data.predicate = def;
      atrie->release_node = release_answer_node;
      atrie->data.variant = node;
      symb = trie_symbol(atrie);

#ifdef O_PLMT
      if ( shared )
      { set(atrie, TRIE_ISSHARED);
	if ( COMPARE_AND_SWAP_WORD(&node->value, 0, symb) )
	{ set(node, TN_PRIMARY);
	  ATOMIC_INC(&variants->value_count);
	} else
	{ release_trie_ref(symb);
	  PL_unregister_atom(symb);
	  atrie = symbol_trie(word2atom(node->value));
	}
      } else
#endif
      { set(node, TN_PRIMARY);
	node->value = symb;
	ATOMIC_INC(&variants->value_count);
      }
    } else
    { discardBuffer(&vars);
      return NULL;
    }

#ifdef O_PLMT
    if ( !claim_answer_table(atrie, clrefp, flags) )
    { discardBuffer(&vars);
      return NULL;
    }
#endif

    if ( ret )
    { if ( isEmptyBuffer(&vars) )		/* TBD: only needed first time */
      { if ( WL_IS_WORKLIST(atrie->data.worklist) )
	{ atrie->data.worklist->ground = true;
	} else if ( !atrie->data.worklist )
	{ atrie->data.worklist = WL_GROUND;
	}
	if ( !PL_unify_atom(ret, ATOM_ret) )
	  atrie = NULL;
      } else
      { int rc;

	if ( (rc=unify_trie_ret(ret, &vars)) != true )
	{ if ( rc < 0 )
	  { Undo(m);
	    emptyBuffer(&vars, (size_t)-1);
	    if ( makeMoreStackSpace(rc, ALLOW_GC) )
	      goto retry;
	  }
	  atrie = NULL;
	}
      }
    }
    discardBuffer(&vars);

    return atrie;
  } else
  { discardBuffer(&vars);
  }

  trie_error(rc, t);
  return NULL;
}


void
clearThreadTablingData(PL_local_data_t *ld)
{ reset_global_worklist(ld->tabling.component);
  reset_newly_created_worklists(ld->tabling.component, WLFS_KEEP_COMPLETE);
  clear_variant_table(&ld->tabling.variant_table);
}


		 /*******************************
		 *   CALL SUBSUPTION INDEXING	*
		 *******************************/

#define suspension_keys(instance) LDFUNC(suspension_keys, instance)
static sindex_key *
suspension_keys(DECL_LD term_t instance)
{ Word p = valTermRef(instance);

  deRef(p);
  if ( isTerm(*p) )
  { Functor f = valueTerm(*p);
    size_t i, arity = arityFunctor(f->definition);
    sindex_key keys[SINDEX_MAX];
    sindex_key *k = keys;

    if ( arity > SINDEX_MAX )
      arity = SINDEX_MAX;

    for(i=0; i<arity; i++)
    { word ki = index_of_word(f->arguments[i]);

      if ( ki )
      { k->argn = i+1;
	k->key  = (unsigned int)ki;
	if ( ++k >= &keys[SINDEX_MAX-1] )
	  break;
      }
    }

    if ( k > keys )
    { k->argn = 0;
      k->key  = 0;
      k++;

      size_t bytes = (char*)k - (char*)keys;
      sindex_key *gk = malloc(bytes);

      if ( gk )
	memcpy(gk, keys, bytes);
      return gk;
    }
  }

  return NULL;
}


static int
suspension_matches_index(const suspension *susp, const sindex_key *skeys)
{ if ( likely(susp->keys!=NULL) )
  { sindex_key *k;

    for(k=susp->keys; k->argn; k++)
    { const sindex_key *sk = &skeys[k->argn];

      if ( unlikely(k->key != sk->key) && likely(!!sk->key) )
	return false;
    }
  }

  return true;
}


#define suspension_matches(answer, susp) LDFUNC(suspension_matches, answer, susp)
static int
suspension_matches(DECL_LD term_t answer, const suspension *susp)
{ fid_t fid;
  term_t tmp;

  if ( (fid=PL_open_foreign_frame()) &&
       (tmp = PL_new_term_ref()) &&
       PL_recorded(susp->instance, tmp) )
  { int ok;

    DEBUG(MSG_TABLING_CALL_SUBSUMPTION,
	  Sdprintf("Skeleton: ");
	  PL_write_term(Serror, tmp, 1200, 0);
	  Sdprintf(", instance: ");
	  PL_write_term(Serror, answer, 1200, PL_WRT_NEWLINE));

    ok = PL_unify(tmp, answer);
    PL_discard_foreign_frame(fid);

    return ok ? true : PL_exception(0) ? -1 : false;
  } else
    return -1;
}

		 /*******************************
		 *  ANSWER/SUSPENSION CLUSTERS	*
		 *******************************/

static cluster *
new_answer_cluster(worklist *wl, answer *ans)
{ cluster *c;

  if ( (c=wl->free_clusters) )
  { wl->free_clusters = c->next;
    c->type = CLUSTER_ANSWERS;
  } else
  { c = PL_malloc(sizeof(*c));
    c->type = CLUSTER_ANSWERS;
    initBuffer(&c->members);
  }
  addBuffer(&c->members, *ans, answer);

  return c;
}

static void
free_answer_cluster(cluster *c)
{ discardBuffer(&c->members);
  PL_free(c);
}

static void
add_to_answer_cluster(cluster *c, answer *ans)
{ addBuffer(&c->members, *ans, answer);
}

static void
merge_answer_clusters(cluster *to, cluster *from)
{ typedef answer* Answer;

  addMultipleBuffer(&to->members,
		    baseBuffer(&from->members, answer),
		    entriesBuffer(&from->members, answer),
		    Answer);
}

static answer *
get_answer_from_cluster(cluster *c, size_t index)
{ return &fetchBuffer(&c->members, index, answer);
}

static size_t
prune_answer_cluster(cluster *c)
{ answer *base = baseBuffer(&c->members, answer);
  answer *top  = topBuffer(&c->members, answer);
  answer *out  = base;

  for( ; base < top; base++)
  { trie_node *n = base->node;
    if ( n->value )
      *out++ = *base;
    else
      prune_node(NULL, n);
  }

  c->members.top = (char*)out;

  return top-out;
}

static inline record_t
TNOT(record_t r, int is_tnot)
{ return (record_t)(((uintptr_t)r)|is_tnot);
}

static inline record_t
UNTNOT(record_t r)
{ return (record_t)(((uintptr_t)r)&~(uintptr_t)1);
}

static int
IS_TNOT(record_t r)
{ return (uintptr_t)r & 0x1;
}

#define new_suspension(sp, term, is_tnot, instance) LDFUNC(new_suspension, sp, term, is_tnot, instance)
static int
new_suspension(DECL_LD suspension *sp, term_t term, int is_tnot,
	       term_t instance)
{ if ( !(sp->term=PL_record(term)) )
    return false;

  if ( unlikely(instance) )
  { if ( !(sp->instance=PL_record(instance)) )
    { PL_erase(sp->term);
      return false;
    }
    sp->keys = suspension_keys(instance);
  } else
  { sp->instance = 0;
    sp->keys = NULL;
  }

  sp->term = TNOT(sp->term, is_tnot);

  return true;
}


#define new_suspension_cluster(wl, first, is_tnot, instance) LDFUNC(new_suspension_cluster, wl, first, is_tnot, instance)
static cluster *
new_suspension_cluster(DECL_LD worklist *wl, term_t first, int is_tnot,
		       term_t instance)
{ cluster *c;
  suspension s;

  if ( !new_suspension(&s, first, is_tnot, instance) )
    return NULL;

  if ( (c=wl->free_clusters) )
  { wl->free_clusters = c->next;
    c->type = CLUSTER_SUSPENSIONS;
  } else
  { c = PL_malloc(sizeof(*c));
    c->type = CLUSTER_SUSPENSIONS;
    initBuffer(&c->members);
  }
  addBuffer(&c->members, s, suspension);

  return c;
}

static void
free_suspension_cluster(cluster *c)
{ suspension *base = baseBuffer(&c->members, suspension);
  size_t entries = entriesBuffer(&c->members, suspension);
  size_t i;

  for(i=0; i<entries; i++)
  { suspension *s = &base[i];

    PL_erase(UNTNOT(s->term));
    if ( s->instance )
      PL_erase(s->instance);
    if ( s->keys )
      free(s->keys);
  }

  discardBuffer(&c->members);
  PL_free(c);
}

#define add_to_suspension_cluster(c, sterm, is_tnot, instance) LDFUNC(add_to_suspension_cluster, c, sterm, is_tnot, instance)
static int
add_to_suspension_cluster(DECL_LD cluster *c, term_t sterm, int is_tnot,
			  term_t instance)
{ suspension s;

  if ( !new_suspension(&s, sterm, is_tnot, instance) )
    return false;
  addBuffer(&c->members, s, suspension);

  return true;
}

static void
merge_suspension_cluster(cluster *to, cluster *from, int do_free)
{ typedef suspension* Suspension;

  addMultipleBuffer(&to->members,
		    baseBuffer(&from->members, suspension*),
		    entriesBuffer(&from->members, suspension*),
		    Suspension);
  if ( do_free )
  { discardBuffer(&from->members);
    PL_free(from);
  }
}


static suspension *
get_suspension_from_cluster(cluster *c, size_t index)
{ DEBUG(CHK_SECURE, assert(index < entriesBuffer(&c->members, suspension)));
  return &fetchBuffer(&c->members, index, suspension);
}

static void
free_cluster(cluster *c)
{ if ( c->type == CLUSTER_ANSWERS )
    free_answer_cluster(c);
  else
    free_suspension_cluster(c);
}

static int
acp_size(cluster *c)
{ return entriesBuffer(&c->members, answer);
}

static int
scp_size(cluster *c)
{ return entriesBuffer(&c->members, suspension);
}

		 /*******************************
		 *	   TABLE WORKLIST	*
		 *******************************/

static worklist *
new_worklist(trie *trie)
{ worklist *wl;

  wl = PL_malloc(sizeof(*wl));
  memset(wl, 0, sizeof(*wl));
  wl->magic = WORKLIST_MAGIC;
  wl->table = trie;
  if ( trie->data.worklist == WL_GROUND )
    wl->ground = true;
  initBuffer(&wl->delays);
  initBuffer(&wl->pos_undefined);
  trie->data.worklist = wl;

  return wl;
}


static void
free_worklist(worklist *wl)
{ cluster *c, *next;
  trie *atrie;

  assert(wl->magic == WORKLIST_MAGIC);
  wl->magic = 0;

  if ( (atrie=wl->table) && atrie->data.worklist )
  { if ( atrie->data.worklist == wl )
      atrie->data.worklist = NULL;
    else
      Sdprintf("Oops, worklist trie doesn't point back at me!\n");
  }

  for(c=wl->head; c; c = next)
  { next = c->next;
    free_cluster(c);
  }
  for(c=wl->free_clusters; c; c = next)
  { next = c->next;
    free_cluster(c);
  }
  discardBuffer(&wl->delays);
  discardBuffer(&wl->pos_undefined);

  PL_free(wl);
}


static void
clean_worklist(worklist *wl)
{ cluster *c, *next;

  wl->riac = NULL;
  if ( wl->head )
  { for(c=wl->head; c; c = next)
    { next = c->next;
      free_cluster(c);
    }
    wl->head = wl->tail = NULL;
  }

  if ( wl->free_clusters )
  { for(c=wl->free_clusters; c; c = next)
    { next = c->next;
      free_cluster(c);
    }
    wl->free_clusters = NULL;
  }
}


#define complete_worklist(wl, destroy) LDFUNC(complete_worklist, wl, destroy)
static void
complete_worklist(DECL_LD worklist *wl, int destroy)
{ trie *atrie = wl->table;

  if ( tt_has_modified_dependencies(atrie) )
    tt_add_table(atrie, TT_TBL_INVALIDATE);

  if ( destroy )
  { free_worklist(wl);
    COMPLETE_WORKLIST(atrie,
		      { atrie->data.worklist = NULL;
			set(atrie, TRIE_COMPLETE);
		      });
  } else
  { clean_worklist(wl);

    COMPLETE_WORKLIST(atrie,
		      { set(atrie, TRIE_COMPLETE);
		      });
  }
}


static int
worklist_negative(worklist *wl)
{ if ( !wl->negative )
  { wl->negative = true;
    add_delay_worklist(wl);
    if ( wl->component->neg_status == SCC_NEG_NONE )
      wl->component->neg_status = SCC_NEG_DELAY;
  }

  return true;
}


/*
 * Remove deleted answers from a worklist.  Deleted answers
 * are normally caused by answer subsumption where the answer
 * is a secondary node in the trie.  As old secondary nodes
 * are replaced by new ones, the worklist may contain deleted
 * nodes.  This removes these nodes from the answer clusters.
 * as well as from the answer tries.  It is called after adding
 * a new subsuming answer has created enough garbage or, when
 * the worklist is executing, as soon as the worklist execution
 * is complete.
 */

static size_t
prune_answers_worklist(worklist *wl)
{ cluster *c;
  size_t gained = 0;

  for(c=wl->head; c; c=c->next)
  { if ( c->type == CLUSTER_ANSWERS )
      gained += prune_answer_cluster(c);
  }

  DEBUG(MSG_TABLING_MODED,
	Sdprintf("Pruned %zd answers\n", gained));

  return gained;
}


/* The work is done if there is no answer cluster or there is
   no suspension right of the answer cluster
*/

static int
worklist_work_done(worklist *wl)
{ return !wl->riac || !wl->riac->next;
}


static void
wkl_append_left(worklist *wl, cluster *c)
{ if ( wl->head )
  { c->prev = NULL;
    c->next = wl->head;
    wl->head->prev = c;
    wl->head = c;
  } else
  { c->next = c->prev = NULL;
    wl->head = wl->tail = c;
  }
}


static void
wkl_append_right(worklist *wl, cluster *c)
{ if ( wl->tail )
  { c->next = NULL;
    c->prev = wl->tail;
    wl->tail->next = c;
    wl->tail = c;
  } else
  { c->next = c->prev = NULL;
    wl->head = wl->tail = c;
  }
}


static void
update_riac(worklist *wl, cluster *acp)
{ cluster *c;

  if ( !acp->next ||
       acp->next->type == CLUSTER_ANSWERS )
  { for(c=acp->prev; c; c = c->prev)
    { if ( c->type == CLUSTER_ANSWERS )
      { wl->riac = c;
	return;
      }
    }

    wl->riac = NULL;
  }
}


static void
wkl_swap_clusters(worklist *wl, cluster *acp, cluster *scp)
{ cluster *a = acp->prev;		/* before the couple */
  cluster *z = scp->next;		/* after the couple */

  assert(acp->next == scp);

  if ( a ) a->next = scp; else wl->head = scp;
  if ( z ) z->prev = acp; else wl->tail = acp;
  scp->prev = a;
  acp->next = z;
  scp->next = acp;
  acp->prev = scp;

  update_riac(wl, acp);

  DEBUG(MSG_TABLING_WORK, print_worklist("Swapped: ", wl));
}


#define potentially_add_to_global_worklist(wl) LDFUNC(potentially_add_to_global_worklist, wl)
static void
potentially_add_to_global_worklist(DECL_LD worklist *wl)
{ if ( !wl->in_global_wl && !wl->executing )
    add_global_worklist(wl);
}


static int
wkl_add_answer(DECL_LD worklist *wl, trie_node *an)
{ potentially_add_to_global_worklist(wl);
  answer ans = {an};

  if ( !answer_is_conditional(an) )
    wl->has_answers = true;

  if ( wl->head && wl->head->type == CLUSTER_ANSWERS )
  { add_to_answer_cluster(wl->head, &ans);
  } else
  { cluster *c = new_answer_cluster(wl, &ans);
    wkl_append_left(wl, c);
    if ( !wl->riac )
      wl->riac = c;
  }
  DEBUG(MSG_TABLING_WORK,
	{ print_worklist("Added answer: ", wl);
	});

  return true;
}


#define wkl_add_suspension(wl, suspension, is_tnot, inst) LDFUNC(wkl_add_suspension, wl, suspension, is_tnot, inst)
static int
wkl_add_suspension(DECL_LD worklist *wl, term_t suspension, int is_tnot,
		   term_t inst)
{ potentially_add_to_global_worklist(wl);
  if ( wl->tail && wl->tail->type == CLUSTER_SUSPENSIONS )
  { if ( !add_to_suspension_cluster(wl->tail, suspension, is_tnot, inst) )
      return false;
  } else
  { cluster *c = new_suspension_cluster(wl, suspension, is_tnot, inst);
    if ( !c )
      return false;
    wkl_append_right(wl, c);
    if ( c->prev && c->prev->type == CLUSTER_ANSWERS )
      wl->riac = c->prev;
  }
  DEBUG(MSG_TABLING_WORK, print_worklist("Added suspension: ", wl));

  return true;
}


#ifdef O_DEBUG
static void
print_worklist(const char *prefix, worklist *wl)
{ cluster *c;

  Sdprintf("%s", prefix);
  for(c=wl->head; c; c=c->next)
  { if ( c->type == CLUSTER_ANSWERS )
    { Sdprintf("ACP(%d)%s ", acp_size(c), c == wl->riac ? "[RIAC]" : "");
    } else
    { Sdprintf("SCP(%d) ", scp_size(c));
    }
  }
  Sdprintf("\n");
}
#endif



		 /*******************************
		 *	PROLOG CONNECTION	*
		 *******************************/

#define unify_fresh(t, atrie, def, create) LDFUNC(unify_fresh, t, atrie, def, create)
static int
unify_fresh(DECL_LD term_t t, trie *atrie, Definition def, int create)
{ if ( create )
  { tbl_component *scc = tbl_create_subcomponent(atrie);
    worklist *wl = tbl_add_worklist(atrie, scc);

    if ( wl )
    { wl->predicate = def;
      return PL_unify_term(t, PL_FUNCTOR, FUNCTOR_fresh2,
				 PL_POINTER, scc,
				 PL_POINTER, wl);
    } else
    { return false;
    }
  } else
  { return PL_unify_atom(t, ATOM_fresh);
  }
}


#define complete_or_invalid_status(atrie, create) \
	LDFUNC(complete_or_invalid_status, atrie, create)
static atom_t
complete_or_invalid_status(DECL_LD trie *atrie, int create)
{ idg_node *n;

  if ( (n=atrie->data.IDG) )
  { if ( n->monotonic && !n->lazy && !n->force_reeval )
      return ATOM_complete;
    if ( n->monotonic && n->lazy && LD->tabling.in_assert_propagation && !create )
      return ATOM_complete;
    if ( n->falsecount > 0 )
      return ATOM_invalid;
    if ( n->reevaluating )
      return ATOM_fresh;
  }

  return ATOM_complete;
}


#define unify_complete_or_invalid(t, atrie, def, create) LDFUNC(unify_complete_or_invalid, t, atrie, def, create)
static int
unify_complete_or_invalid(DECL_LD term_t t, trie *atrie,
			  Definition def, int create)
{ atom_t status = complete_or_invalid_status(atrie, create);

  if ( status == ATOM_fresh && create )
    return unify_fresh(t, atrie, def, create);
  else
    return PL_unify_atom(t, status);
}


/** unify_table_status(DECL_LD term_t t, trie *trie, Definition def, int create)
 *
 * @param `t` is unified with the status of `trie`.  Possible values
 * are:
 *
 *   - A worklist (if the trie is incomplete)
 *   - `complete`
 *   - `invalid`
 *   - `dynamic` (for pseudo answer tries representing an incremental
 *     dynamic predicate)
 *   - `fresh` (if `create` is `false`)
 *   - `fresh(SCC, WL)` (if `create` is `true`)
 *
 * @param `create` If `true`, we are going to use this worklist for
 * filling the trie.  This is used by '$tbl_variant_table'/6 and
 * friends.
 */

#define unify_table_status(t, trie, def, create) LDFUNC(unify_table_status, t, trie, def, create)
static int
unify_table_status(DECL_LD term_t t, trie *trie, Definition def, int create)
{ if ( ison(trie, TRIE_COMPLETE) )
  { return unify_complete_or_invalid(t, trie, def, create);
  } else
  { worklist *wl = trie->data.worklist;

    if ( WL_IS_WORKLIST(wl) )
    { if ( create && wl->component != LD->tabling.component )
      { DEBUG(MSG_TABLING_WORK,
	      Sdprintf("Merging into %p (current = %p)\n",
		       wl->component, LD->tabling.component));
	merge_component(wl->component);
	LD->tabling.component = wl->component;
      }

      return PL_unify_pointer(t, wl);
    }

    if ( wl == WL_DYNAMIC )
      return PL_unify_atom(t, ATOM_dynamic);

    assert(!wl || wl == WL_GROUND);
    return unify_fresh(t, trie, def, create);
  }
}


#define table_status(trie) LDFUNC(table_status, trie)
static atom_t
table_status(DECL_LD trie *trie)
{ if ( ison(trie, TRIE_COMPLETE) )
  { return complete_or_invalid_status(trie, false);
  } else
  { worklist *wl = trie->data.worklist;

    if ( WL_IS_WORKLIST(wl) )
      return ATOM_incomplete;
    else if ( wl == WL_DYNAMIC )
      return ATOM_dynamic;
    else
      return ATOM_fresh;
  }
}


static bool
table_is_incomplete(trie *trie)
{ return ( WL_IS_WORKLIST(trie->data.worklist) &&
	   isoff(trie, TRIE_COMPLETE) );
}


static bool
unify_skeleton(DECL_LD trie *atrie, term_t wrapper, term_t skeleton)
{ if ( !wrapper && !(wrapper=PL_new_term_ref()) )
    return false;

  if ( atrie->data.variant &&
       unify_trie_term(atrie->data.variant, NULL, wrapper) )
  { worklist *wl = atrie->data.worklist;
    Definition def = WL_IS_WORKLIST(wl) ? wl->predicate : NULL;
    int flags = ison(atrie, TRIE_ISSHARED) ? AT_SHARED : AT_PRIVATE;
    return ( get_answer_table(def, wrapper, skeleton,
			      NULL, flags|AT_NOCLAIM) != NULL);
  }

  return false;
}


static bool
get_scc(term_t t, tbl_component **cp)
{ void *ptr;

  if ( PL_get_pointer_ex(t, &ptr) )
  { tbl_component *c = ptr;

    if ( c->magic != COMPONENT_MAGIC )
      return PL_existence_error("table component", t),false;

    *cp = c;

    return true;
  }

  return false;
}

#define get_worklist(t, wlp) LDFUNC(get_worklist, t, wlp)
static bool
get_worklist(DECL_LD term_t t, worklist **wlp)
{ void *ptr;

  if ( PL_get_pointer(t, &ptr) )
  { worklist *wl = ptr;
    assert(wl->magic == WORKLIST_MAGIC);
    *wlp = wl;
    return true;
  }

  return PL_type_error("worklist", t),false;
}


static bool
tnot_get_worklist(term_t t, worklist **wlp, int *is_tnot)
{ GET_LD
  void *ptr;

  if ( PL_get_pointer(t, &ptr) )
  { worklist *wl = ptr;
    assert(wl->magic == WORKLIST_MAGIC);
    *wlp = wl;
    *is_tnot = false;
    return true;
  }

  if ( PL_is_functor(t, FUNCTOR_tnot1) )
  { term_t a = PL_new_term_ref();
    _PL_get_arg(1, t, a);
    if ( PL_get_pointer(a, &ptr) )
    { worklist *wl = ptr;
      assert(wl->magic == WORKLIST_MAGIC);
      *wlp = wl;
      *is_tnot = true;
      return true;
    }
  }

  return PL_type_error("worklist", t),false;
}


static worklist *
tbl_add_worklist(trie *atrie, tbl_component *scc)
{ worklist *wl;

  if ( !WL_IS_WORKLIST(wl=atrie->data.worklist) )
    wl = new_worklist(atrie);

  wl->component = scc;
  add_global_worklist(wl);
  add_newly_created_worklist(wl);
  clear(atrie, TRIE_COMPLETE);

  return wl;
}


static bool
destroy_answer_trie(trie *atrie)
{ if ( atrie->data.variant)
  { trie *vtrie = get_trie_from_node(atrie->data.variant);

    if ( is_variant_trie(vtrie) )
    { DEBUG(MSG_TABLING_VTRIE_DEPENDENCIES,
	    print_answer_table(atrie, "Delete answer trie for"));

      if ( ison(atrie, TRIE_ISSHARED) )
      { COMPLETE_WORKLIST(atrie,		/* lock might be overkill */
			  reset_answer_table(atrie, false));
      } else
	trie_delete(vtrie, atrie->data.variant, true);

      return true;
    }
  }

  return false;
}


static bool
delayed_destroy_table(trie *atrie)
{ if ( table_is_incomplete(atrie) )
  { set(atrie, TRIE_ABOLISH_ON_COMPLETE);
    DEBUG(MSG_TABLING_ABOLISH,
	  print_answer_table(atrie, "Scheduling for delayed abolish"));
    return true;
  }

  return false;
}

static bool
abolish_table(trie *atrie)
{ if ( atrie->data.worklist == WL_DYNAMIC )
    return true;		/* quickly ignore dynamic pseudo tables */

  if ( atrie->data.variant)
  { trie *vtrie = get_trie_from_node(atrie->data.variant);

    if ( is_variant_trie(vtrie) )
    {
#ifdef O_PLMT
      int mytid = PL_thread_self();

      if ( ison(atrie, TRIE_ISSHARED) )
      { LOCK_SHARED_TABLE(atrie);
	if ( !atrie->tid )			/* no owner */
	{ take_trie(atrie, mytid);
	  assert(!table_is_incomplete(atrie));
	  reset_answer_table(atrie, false);
	  drop_trie(atrie);
	} else if ( atrie->tid == mytid )	/* I am the owner */
	{ if ( !delayed_destroy_table(atrie) )
	  { reset_answer_table(atrie, false);
	    drop_trie(atrie);
	    cv_broadcast(&GD->tabling.cvar);
	  }
	} else
	{ set(atrie, TRIE_ABOLISH_ON_COMPLETE);
	  DEBUG(MSG_TABLING_ABOLISH,
		print_answer_table(atrie, "Scheduling for delayed abolish"));
	}
	UNLOCK_SHARED_TABLE(atrie);
      } else
#endif
      { if ( !delayed_destroy_table(atrie) )
	  trie_delete(vtrie, atrie->data.variant, true);
      }

      return true;
    }
  }

  return true;
}

/** '$tbl_destroy_table'(+Trie)
 *
 * Destroy a single trie table.  Succeeds silently if the answer trie
 * has already been destroyed.
 */

static
PRED_IMPL("$tbl_destroy_table", 1, tbl_destroy_table, 0)
{ trie *atrie;

  if ( get_trie(A1, &atrie) )
    return abolish_table(atrie);

  return false;
}


/** '$tbl_pop_worklist'(+SCC, -Worklist) is semidet.
 *
 * Pop next worklist from the component.
 */

static
PRED_IMPL("$tbl_pop_worklist", 2, tbl_pop_worklist, 0)
{ PRED_LD
  tbl_component *scc;

  if ( get_scc(A1, &scc) )
  { if ( scc->status == SCC_ACTIVE )
    { worklist *wl;

      if ( (wl=pop_worklist(scc)) )
	return PL_unify_pointer(A2, wl);

      if (
#ifndef O_AC_EAGER
	    scc->simplifications ||
#endif
	    scc->neg_status != SCC_NEG_NONE )
      { if ( (wl=negative_worklist(scc)) )
	  return PL_unify_pointer(A2, wl);
      }
    }
  }

  return false;
}

/** '$tbl_wkl_add_answer'(+Worklist, +Answer, +Delays, -Complete) is semidet.
 *
 * Add an answer to the worklist's trie  and the worklist answer cluster
 * using trie_insert_new/3. Fails if a  variant   of  Term is already in
 * Worklist.
 *
 * @arg Answer is either a ret/N (normal tabling) or a (ret/N)/ModeArgs
 * term (answer subsumption).
 */

#define pred_max_table_answer_size(def) LDFUNC(pred_max_table_answer_size, def)
static inline size_t
pred_max_table_answer_size(DECL_LD const Definition def)
{ size_t limit;

  limit = def->tabling ? def->tabling->answer_abstract : (size_t)-1;
  if ( limit == (size_t)-1 )
    limit = LD->tabling.restraint.max_table_answer_size;

  return limit;
}


static
PRED_IMPL("$tbl_wkl_add_answer", 4, tbl_wkl_add_answer, 0)
{ PRED_LD
  worklist *wl;

  if ( get_worklist(A1, &wl) )
  { Word kp;
    trie_node *node;
    atom_t action;
    size_abstract sa = {.from_depth = 2};
    int rc;

#ifdef O_PLMT
    DEBUG(0, assert(isoff(wl->table, TRIE_ISSHARED) || wl->table->tid));
#endif

    kp = valTermRef(A2);
    if ( ison(wl->table, TRIE_ISMAP) )
      return !!wkl_mode_add_answer(wl, wl->table, A2, A3);

    sa.size = pred_max_table_answer_size(wl->predicate);
    rc = trie_lookup_abstract(wl->table, NULL, &node, kp,
			      true, &sa, NULL);
    if ( rc > 0 )				/* ok or abstracted */
    { idg_node *idg;

      if ( rc == TRIE_ABSTRACTED )
      { atom_t action = LD->tabling.restraint.max_table_answer_size_action;

	DEBUG(MSG_TABLING_RESTRAINT,
	      print_answer_table(wl->table, "Max answer size exceeded"));

	if ( action == ATOM_bounded_rationality )
	{ if ( !add_radial_restraint() )
	    return false;
	} else if ( action == ATOM_fail ||
		    !tbl_wl_tripwire(wl, action, ATOM_max_table_answer_size) )
	{ trie_delete(wl->table, node, true);
	  return false;
	}
      }

      if ( node->value )
      { if ( node->value == ATOM_trienode )
	{ if ( ison(node, TN_IDG_DELETED) )
	  { clear(node, TN_IDG_DELETED);
	    goto update_dl;
	  } else
	  { if ( answer_is_conditional(node) )
	    { if ( update_delay_list(wl, node, A2, A3) == UDL_COMPLETE )
		return PL_unify_atom(A4, ATOM_cut);
	    }
	  }

	  return false;				/* already in trie */
	}
	return PL_permission_error("modify", "trie_key", A2);
      } else if ( (action=tripwire_answers_for_subgoal(wl)) )
      { DEBUG(MSG_TABLING_RESTRAINT,
	      print_answer_table(wl->table, "Answer count exceeded"));
	if ( action == ATOM_bounded_rationality )
	{ term_t gen;

	  trie_delete(wl->table, node, true);

	  if ( !(gen = PL_new_term_ref()) ||
	       !generalise_answer_substitution(A2, gen) ||
	       !add_answer_count_restraint() )
	    return false;

	  kp = valTermRef(gen);
	  rc = trie_lookup(wl->table, NULL, &node, kp, true, NULL);
	  if ( rc == true )
	  { if ( !PL_unify_atom(A4, ATOM_cut) )
	      return false;
	    set_trie_value_word(wl->table, node, ATOM_trienode);
	    if ( update_delay_list(wl, node, A2, A3) == UDL_FALSE )
	      return false;
	    return true;
	  } else
	  { return trie_error(rc, gen);
	  }
	} else
	{ if ( tbl_wl_tripwire(wl, action, ATOM_max_answers_for_subgoal) )
	  { goto add_anyway;
	  } else
	  { trie_delete(wl->table, node, true);
	    return false;
	  }
	}
      } else
      { add_anyway:
	set_trie_value_word(wl->table, node, ATOM_trienode);
	if ( (idg=wl->table->data.IDG) && idg->reevaluating )
	{ set(node, TN_IDG_ADDED);
	  idg->new_answer = true;
	}

      update_dl:
	rc = update_delay_list(wl, node, A2, A3);

	switch(rc)
	{ case UDL_FALSE:
	    return false;
	  case UDL_COMPLETE:
	    if ( !PL_unify_atom(A4, ATOM_cut) )
	      return false;
	  default:
	    ;
	}

	return wkl_add_answer(wl, node);
      }
    }

    return trie_error(rc, A2);
  }

  return false;
}

/** wkl_mode_add_answer(DECL_LD worklist *wl, trie *trie, term_t answer, term_t delays)
 *
 * Add an answer Args for moded arguments to the worklist's trie and the
 * worklist answer cluster using  trie_insert_new/3   and  mode directed
 * tabling.
 *
 * @param answer is a term Return/ModedArgs
 */

#define AS_NEW_DEFINED 0x1
#define AS_OLD_DEFINED 0x2

typedef struct sa_context
{ worklist  *wl;
  trie	    *atrie;
  trie_node *root;
  trie_node *added;
  term_t     skel;
  term_t     argv;			/* Arguments for '$tabling':update/8 */
  term_t     delays;
  int	     flags;			/* AS_*_DEFINED */
  int	     garbage;			/* # not pruned dummy nodes */
} sa_context;

#define TRIE_MAP_FALSE ((void*)1)	/* error while mapping */
#define TRIE_MAP_DONE  ((void*)2)	/* found existing answer subsuming new */
#define TRIE_MAP_TRUE  NULL		/* mapped all nodes */

/* - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - -
add_subsuming_answer() adds a new aggregate value   as  a secondary node
below `root`. If `old` is  present,  the   new  value  replaces  the one
pointer to by `old`. This poses two problems.

  - We must remove `old` from its answer cluster.  We have little clue
    about which answer cluster holds the `old` answer though.  Adding
    data in the node to help finding the cluster is not that useful
    as clusters can be merged and the answer array may be relocated.

  - We must prune `old` from the trie. If we do not, we waste a lot
    of memory and update_subsuming_answers(), using map_trie_node()
    becomes slow, resulting in quadratic complexity.

These issues are currently resolved  by calling prune_answers_worklist()
and prune_trie() if there are more than   10 deleted answers. The number
10 should depend on

  - The ratio (deleted answers/real answers) in the worklist's answer
    clusters as the prune time is proportional to the total number
    of deleted plus real answers in these clusters.
  - The ration (prunable trie nodes/total trie nodes) in the answer
    trie as this refers wasted memory and map_trie_node() walking over
    deleted nodes.

Returns the added secundary node if a   new  aggregated value was set or
NULL when no new value was set or some error happened.
- - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - */

#define add_subsuming_answer(wl, atrie, root, skel, old, margs, delays) LDFUNC(add_subsuming_answer, wl, atrie, root, skel, old, margs, delays)
static trie_node *
add_subsuming_answer(DECL_LD worklist *wl, trie *atrie, trie_node *root, term_t skel,
		     trie_node *old, term_t margs, term_t delays)
{ trie_node *node;
  Word vp;
  int rc;

  vp = valTermRef(margs);
  rc = trie_lookup(atrie, root, &node, vp, true, NULL);
  if ( rc == true )
  { if ( isoff(node, TN_SECONDARY) )
    { node->value = ATOM_trienode;
      set(node, TN_SECONDARY);

      if ( old )
	trie_delete(atrie, old, false);

      if ( wl )
      { if ( update_delay_list(wl, node, skel, delays) == UDL_FALSE )
	  return NULL;

	wkl_add_answer(wl, node);
      }
      return node;
    } else
    { if ( ison(node, TN_IDG_DELETED) )
	clear(node, TN_IDG_DELETED);

      if ( wl && answer_is_conditional(node) )
       update_delay_list(wl, node, skel, delays);
    }

    return NULL;			/* no change */
  } else
  { term_t trie;

    if ( (trie = PL_new_term_ref()) &&
	 PL_unify_atomic(trie, atrie->symbol) )
      trie_error(rc, trie);

    return NULL;
  }
}


/* - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - -
Calls

    '$tabling':update(+Flags, +Head, +Module, +Old, +New, -Agg, -Action)
		      av+0,    av+1,  av+2,    av+3, av+4, av+5, av+6
- - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - */

static void *
update_subsuming_answer(trie_node *node, void *ptr)
{ sa_context *ctx = ptr;

  if ( ison(node, TN_SECONDARY) )
  { GET_LD
    predicate_t PRED_update7;
    term_t av = ctx->argv;
    term_t agg = av+5;
    term_t action = av+6;
    atom_t conditional = answer_is_conditional(node) ? 0
						     : AS_OLD_DEFINED;

    PRED_update7 = _PL_predicate("update", 7, "$tabling",
				 &GD->procedures.update7);

    if ( tbl_put_moded_args(av+3, node) &&
	 PL_put_integer(av+0, ctx->flags|conditional) &&
	 PL_put_variable(agg) &&
	 PL_put_variable(action) &&
	 PL_call_predicate(NULL, PL_Q_PASS_EXCEPTION, PRED_update7, av) )
    { trie_node *del;
      atom_t action;

      if ( !PL_get_atom_ex(av+6, &action) )
	return TRIE_MAP_FALSE;

      DEBUG(MSG_TABLING_MODED,
	    { Sdprintf("Updated answer (action = %s): ", PL_atom_chars(action));
	      PL_write_term(Serror, av+3, 1200, 0);
	      Sdprintf(" to ");
	      PL_write_term(Serror, agg, 1200, PL_WRT_NEWLINE);
	    });

      if ( action == ATOM_done )
	return TRIE_MAP_DONE;
      else if ( action == ATOM_keep )
	del = NULL;
      else
	del = node;

      if ( (ctx->added = add_subsuming_answer(ctx->wl, ctx->atrie, ctx->root,
					      ctx->skel, del, agg,
					      ctx->delays)) )
	return TRIE_MAP_TRUE;

      return TRIE_MAP_FALSE;
    } else
    { if ( PL_exception(0) )
	return TRIE_MAP_FALSE;
      DEBUG(MSG_TABLING_MODED, Sdprintf("No change!\n"));
      return TRIE_MAP_TRUE;
    }
  } else
  { if ( !node->children.any )
      ctx->garbage++;

    return TRIE_MAP_TRUE;
  }
}


#define update_subsuming_answers(wl, atrie, root, skel, margs, delays) LDFUNC(update_subsuming_answers, wl, atrie, root, skel, margs, delays)
static trie_node *
update_subsuming_answers(DECL_LD worklist *wl, trie *atrie, trie_node *root, term_t skel,
			 term_t margs, term_t delays)
{ Word ldlp;
  Word gdlp;

  sa_context ctx = { .wl      = wl,
		     .atrie   = atrie,
		     .root    = root,
		     .added   = NULL,
		     .skel    = skel,
		     .delays  = delays,
		     .flags   = 0,
		     .garbage = 0
		   };

  if ( !( (ctx.argv = PL_new_term_refs(7)) &&
	  PL_put_functor(ctx.argv+1, atrie->data.predicate->functor->functor) &&
	  PL_put_atom(ctx.argv+2,    atrie->data.predicate->module->name) &&
	  PL_put_term(ctx.argv+4,    margs) ) )
    return NULL;

  if ( delays )				/* normal tabling */
  { deRef2(valTermRef(LD->tabling.delay_list), gdlp);
    gdlp = argTermP(*gdlp, 0);
    deRef(gdlp);
    deRef2(valTermRef(delays), ldlp);

    if ( isNil(*ldlp) && isNil(*gdlp) )
      ctx.flags = AS_NEW_DEFINED;
  } else
  { ctx.flags = AS_NEW_DEFINED;		/* monotonic tabling */
  }

  if ( map_trie_node(root, update_subsuming_answer, &ctx) == TRIE_MAP_FALSE )
    return NULL;

  if ( ctx.garbage > 10 )
  { if ( wl )
    { if ( wl->executing )
	wl->needs_answer_gc = 1;
      else
	prune_answers_worklist(wl);
    } else				/* monotonic tabling */
    { idg_node *idg;

      if ( (idg=atrie->data.IDG) && idg->lazy )
	prune_deleted_mdeps(idg);

      prune_trie(atrie, root, NULL, NULL);
    }
  }

  return ctx.added;
}


static trie_node *
wkl_mode_add_answer(DECL_LD worklist *wl, trie *atrie,
		    term_t answer, term_t delays)
{ Word kp;
  trie_node *root;
  int rc;
  term_t av = PL_new_term_refs(2);
  term_t skel  = av+0;
  term_t margs = av+1;

  DEBUG(MSG_TABLING_MODED,
	{ print_answer_table(atrie, "New moded answer for");
	});

  kp = valTermRef(answer);
  deRef(kp);
  if ( hasFunctor(*kp, FUNCTOR_divide2) )
  { kp = argTermP(*kp, 0);
    *valTermRef(skel)  = linkValI(kp);
    *valTermRef(margs) = linkValI(kp+1);
  } else
  { return PL_domain_error("moded_answer", answer),NULL;
  }

  rc = trie_lookup(atrie, NULL, &root, kp, true, NULL);
  if ( rc == true )
  { if ( ison(root, TN_PRIMARY) )
    { if ( ison(root, TN_IDG_DELETED) )
      { clear(root, TN_IDG_DELETED);
	 DEBUG(MSG_TABLING_MODED,
	       Sdprintf("First answer while re-evaluating\n"));
	return add_subsuming_answer(wl, atrie, root,
				    skel, NULL, margs, delays);
      } else
      { return update_subsuming_answers(wl, atrie, root,
					skel, margs, delays);
      }
    } else
    { DEBUG(MSG_TABLING_MODED,
	    { Sdprintf("First answer: ");
	      PL_write_term(Serror, margs, 1200, PL_WRT_NEWLINE);
	    });

      set_trie_value_word(atrie, root, ATOM_trienode);
      return add_subsuming_answer(wl, atrie, root,
				  skel, NULL, margs, delays);
    }
  } else
  { return trie_error(rc, skel),NULL;
  }
}


/** '$tbl_wkl_add_suspension'(+Worklist, +Suspension) is det.
 *
 * Add a suspension to the worklist.
 */

static
PRED_IMPL("$tbl_wkl_add_suspension", 2, tbl_wkl_add_suspension, 0)
{ PRED_LD
  worklist *wl;
  int is_tnot;

  if ( tnot_get_worklist(A1, &wl, &is_tnot) )
    return wkl_add_suspension(wl, A2, is_tnot, 0);

  return false;
}

/** '$tbl_wkl_add_suspension'(+Worklist, +Instance, +Suspension) is det.
 *
 * Add a suspension to the worklist for	call subsumtive tabling.  Only
 * answers that unify with Instance must be passed down to Suspension.
 */

static
PRED_IMPL("$tbl_wkl_add_suspension", 3, tbl_wkl_add_suspension, 0)
{ PRED_LD
  worklist *wl;
  int is_tnot;

  if ( tnot_get_worklist(A1, &wl, &is_tnot) )
    return wkl_add_suspension(wl, A3, is_tnot, A2);

  return false;
}



/** '$tbl_wkl_make_follower'(+Worklist) is det.
 *
 * Turn a worklist that used  to  be   a  leader  into  a follower after
 * merging it with a parent SCC. This   implies  we must move the answer
 * clusters in front of the dependency clusters.
 */

static
PRED_IMPL("$tbl_wkl_make_follower", 1, tbl_wkl_make_follower, 0)
{ PRED_LD
  worklist *wl;

  if ( get_worklist(A1, &wl) )
  { cluster *scp = NULL;
    cluster *acp = NULL;
    cluster *c, *next;

    for(c=wl->head; c; c=next)
    { next = c->next;

      if ( c->type == CLUSTER_ANSWERS )
      { if ( acp )
	{ merge_answer_clusters(acp, c);
	  free_answer_cluster(c);
	} else
	{ acp = c;
	  acp->prev = acp->next = NULL;
	}
      } else
      { if ( scp )
	{ merge_suspension_cluster(scp, c, true);
	} else
	{ scp = c;
	  scp->prev = scp->next = NULL;
	}
      }
    }

    wl->head = wl->tail = NULL;
    if ( acp )
    { wkl_append_left(wl, acp);
      wl->riac = acp;
    } else
    { wl->riac = NULL;
    }
    if ( scp )
      wkl_append_right(wl, scp);

    if ( acp && scp )
      add_global_worklist(wl);

    return true;
  }

  return false;
}


/** '$tbl_wkl_done'(+Worklist) is semidet.
 *
 * True if the worklist is complete
 */

static
PRED_IMPL("$tbl_wkl_done", 1, tbl_wkl_done, 0)
{ PRED_LD
  worklist *wl;

  return get_worklist(A1, &wl) && worklist_work_done(wl);
}

/** '$tbl_wkl_negative'(+Worklist) is semidet.
 *
 * True if the worklist is complete
 */

static
PRED_IMPL("$tbl_wkl_negative", 1, tbl_wkl_negative, 0)
{ PRED_LD
  worklist *wl;

  return get_worklist(A1, &wl) && worklist_negative(wl);
}


/** '$tbl_tbl_wkl_is_false'(+Worklist) is semidet.
 *
 * True if the worklist is is  a  negative   node  that  is true (has no
 * definite solutions). This is used at   the end of negation_suspend/4,
 * after we delayed the negation. This  means   we  must fail if we have
 * definite answers, but succeed if  there   are  conditional answers as
 * simplification has not yet been done.
 */

static
PRED_IMPL("$tbl_wkl_is_false", 1, tbl_wkl_is_false, 0)
{ PRED_LD
  worklist *wl;

  if ( get_worklist(A1, &wl) )
  { assert(wl->negative);

    return wl->neg_delayed && !wl->has_answers;
  }

  return false;
}

/** '$tbl_wkl_answer_trie'(+Worklist, -Trie) is det.
 *
 * True when Trie is the answer trie associated with Worklist
 */

static
PRED_IMPL("$tbl_wkl_answer_trie", 2, tbl_wkl_answer_trie, 0)
{ GET_LD
  worklist *wl;

  return ( get_worklist(A1, &wl) &&
	   PL_unify_atom(A2, wl->table->symbol) );
}


/** '$tbl_wkl_work'(+Worklist, -Answer, -ModeArgs,
 *		    -Goal, -Continuation, -Wrapper, -TargetTable,
 *		    -Delays) is nondet.
 *
 * True when Answer must be tried on Suspension.  Backtracking
 * basically does
 *
 *   ```
 *   member(Answer, RIAC),
 *   member(Suspension, LastSuspensionCluster)
 *   ```
 *
 * If the carthesian product is exhausted it tries to re-start using the
 * possible new RIAC and SCP.  During its execution, worklist->executing
 * is true to avoid the worklist to   become part of the global worklist
 * again.
 *
 * This replaces table_get_work/3 from the pure Prolog implementation.
 */

/* - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - -
Unify the 4 arguments  of  the   dependecy  structure  with subsequent 4
output arguments.
- - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - */

#define unify_arg_term(a, v) LDFUNC(unify_arg_term, a, v)
static inline void
unify_arg_term(DECL_LD term_t a, Word v)
{ Word p = valTermRef(a);

  deRef(p);
  DEBUG(CHK_SECURE, assert(isVar(*p)));
  Trail(p, linkValI(v));
}

#define unify_dependency(a0, dependency, wl, answer) LDFUNC(unify_dependency, a0, dependency, wl, answer)
static int
unify_dependency(DECL_LD term_t a0, term_t dependency,
		 worklist *wl, trie_node *answer)
{ if ( ensureStackSpace(10, 5) )
  { term_t srcskel = PL_new_term_ref();
    Word dp = valTermRef(dependency);
    Functor f;

    deRef(dp);
    if ( unlikely(!isTerm(*dp)) )
      return false;
    f = valueTerm(*dp);

    unify_arg_term(srcskel, &f->arguments[0]); /* SrcSkeleton */
    unify_arg_term(a0+1,    &f->arguments[1]); /* Continuation */
    unify_arg_term(a0+2,    &f->arguments[2]); /* TargetSkeleton */
    unify_arg_term(a0+3,    &f->arguments[3]); /* TargetWL */
    unify_arg_term(a0+4,    &f->arguments[4]); /* Delays */

    if ( !PL_unify(srcskel, a0+0) )
      return false;
    if ( !idg_set_current_wl(a0+3) )
      return false;

    if ( unlikely(!answer) )			    /* negative delay */
    { Word p = allocGlobalNoShift(3);

      assert(p);
      p[0] = FUNCTOR_dot2;
      p[1] = wl->table->symbol;

      push_delay_list(p);
    } else if ( unlikely(answer_is_conditional(answer)) )
    { word p5 = delay_to_data(answer, valTermRef(a0+0));
      Word p = allocGlobalNoShift(6);
      assert(p);

      p[0] = FUNCTOR_dot2;
      p[1] = consPtr(&p[3], TAG_COMPOUND|STG_GLOBAL);
      p[3] = FUNCTOR_plus2;
      p[4] = wl->table->symbol;
      p[5] = p5;

      push_delay_list(p);
    }

    return true;
  }

  return false;
}


/* Unify `term` with the Prolog term represented by `node`.  Note that
 * the node can be a secondary value in the case of answer subsumption,
 * in which case a term Ret/ModeArgs is created.
 */

#define tbl_unify_answer(node, term) LDFUNC(tbl_unify_answer, node, term)
static int
tbl_unify_answer(DECL_LD trie_node *node, term_t term)
{ if ( node )
  { if ( unlikely(ison(node, TN_SECONDARY)) )
    { term_t av = PL_new_term_refs(2);

      return ( unify_trie_term(node, &node, av+1) &&
	       unify_trie_term(node, NULL,  av+0) &&
	       PL_cons_functor_v(av+0, FUNCTOR_divide2, av) &&
	       PL_unify_output(term, av+0) );
    } else
    { return unify_trie_term(node, NULL, term);
    }
  }

  return true;				/* for negative dummy solutions */
}


static int
tbl_put_moded_args(DECL_LD term_t t, trie_node *node)
{ if ( node )
  { if ( unlikely(ison(node, TN_SECONDARY)) )
      return unify_trie_term(node, NULL, t);
    else
      return put_trie_value(t, node); /* TBD: Can become ATOM_trienode */
  } else				/* negative dummy solution */
  { *valTermRef(t) = ATOM_trienode;
    return true;
  }
}


static int
advance_wkl_state(wkl_step_state *state)
{ next:

  if ( --state->suspensions.here < state->suspensions.base )
  { state->suspensions.here = state->suspensions.top;
    if ( --state->acp_index == 0 )
    { cluster *acp, *scp;

      /* Merge adjacent suspension clusters */
      if ( (scp=state->scp)->prev && scp->prev->type == CLUSTER_SUSPENSIONS )
      { scp->prev->next = scp->next;
	scp->next->prev = scp->prev;
	merge_suspension_cluster(scp->prev, scp, false);
	seekBuffer(&scp->members, 0, record_t);
	scp->next = state->list->free_clusters;
	state->list->free_clusters = scp;
      }

      /* Merge adjacent answer clusters */
      if ( (acp=state->acp)->next && acp->next->type == CLUSTER_ANSWERS )
      { acp->prev->next = acp->next;
	acp->next->prev = acp->prev;
	merge_answer_clusters(acp->next, acp);
	seekBuffer(&acp->members, 0, answer);
	acp->next = state->list->free_clusters;
	state->list->free_clusters = acp;
      }

      /* If more work, re-initialize */
      if ( (acp=state->list->riac) && (scp=acp->next) )
      { DEBUG(MSG_TABLING_WORK,
	      print_worklist("Next step: ", state->list));
	assert(acp->type == CLUSTER_ANSWERS);
	assert(scp->type == CLUSTER_SUSPENSIONS);
	wkl_swap_clusters(state->list, acp, scp);
	state->acp       = acp;
	state->scp       = scp;
	state->acp_index = acp_size(acp);

	if ( state->acp_index > 0 && scp_size(scp) > 0 )
	{ state->suspensions.base = get_suspension_from_cluster(scp, 0);
	  state->suspensions.top  = get_suspension_from_cluster(scp, scp_size(scp)-1);
	  state->suspensions.here = state->suspensions.top;
	  goto next_answer;
	} else
	{ goto next;
	}
      }

      return false;
    } else
    { next_answer:
      state->answer = get_answer_from_cluster(state->acp, state->acp_index-1);
      state->keys_inited = 0;
    }
  }

  return true;
}


static void
free_wkl_state(wkl_step_state *state)
{ worklist *wl = state->list;

  wl->executing = false;
  freeForeignState(state, sizeof(*state));
  if ( wl->needs_answer_gc )
    prune_answers_worklist(wl);
}


/**
 * '$tbl_wkl_work'(+WorkList,
 *		   -Answer,
 *		   -Continuation, -TargetSkeleton, -TargetWorklist,
 *		   -Delays)
 */

static
PRED_IMPL("$tbl_wkl_work", 6, tbl_wkl_work, PL_FA_NONDETERMINISTIC)
{ PRED_LD
  wkl_step_state *state;
  trie_node *can = NULL;

  switch( CTX_CNTRL )
  { case FRG_FIRST_CALL:
    { worklist *wl;

      if ( get_worklist(A1, &wl) )
      { cluster *acp, *scp;

	if ( (acp=wl->riac) && (scp=acp->next) )
	{ int sz_acp = acp_size(acp);
	  int sz_scp = scp_size(scp);

	  wkl_swap_clusters(wl, acp, scp);

	  if ( sz_acp > 0 && sz_scp > 0 )
	  { DEBUG(MSG_TABLING_WORK,
		  print_worklist("First step: ", wl));
	    state = allocForeignState(sizeof(*state));
	    state->list		    = wl;
	    state->acp		    = acp;
	    state->scp		    = scp;
	    state->acp_index        = sz_acp;
	    state->answer           = get_answer_from_cluster(acp, sz_acp-1);
	    state->suspensions.base = get_suspension_from_cluster(scp, 0);
	    state->suspensions.top  = get_suspension_from_cluster(scp, sz_scp-1);
	    state->suspensions.here = state->suspensions.top;
	    state->keys_inited      = 0;
	    wl->executing	    = true;

	    break;
	  }
	}
      }

      return false;
    }
    case FRG_REDO:
      state = CTX_PTR;
      break;
    case FRG_CUTTED:
      state = CTX_PTR;
      free_wkl_state(state);
      return true;
    default:
      assert(0);
      return false;
  }

  Mark(fli_context->mark);

  do
  { const suspension *sp;
    term_t susp;
    trie_node *an = state->answer->node;

    /* Ignore (1) removed answer due to simplification
     *        (2) dummy restart for delayed negation,
     *        (3) conditional answer for tnot
     */

    if ( (an != NULL && an->value == 0) )	/* removed answer */
    { state->suspensions.here = state->suspensions.base;/* skip all suspensions */
      continue;
    }

    sp = state->suspensions.here;

    if ( (an == NULL && !IS_TNOT(sp->term)) ||
	 (an != NULL && IS_TNOT(sp->term) && answer_is_conditional(an)) )
      continue;

    /* We got an answer we want to pass the suspension cluster.
     * Unify A2 with it and get the first suspension.
     */

    if ( can != an )				/* reuse the answer */
    { if ( can )
	Undo(fli_context->mark);
      if ( !tbl_unify_answer(an, A2) )
	break;					/* resource error */
      can = an;
    }

    /* WFS: need to add a positive node to the delay list if `an`
     * is conditional.  The positive node contains the variant
     * we continue and `an`, but is _independant_ from the
     * condition on `an`.
     */

    /* Call subsumption: filter out suspensions for which the
     * answer does not unify with the answer skeleton for the
     * subsumed table.  Note that this implies that we often
     * hold the same answer (an) against multiple suspensions
     * and therefore we avoid unifying A2 with `an` multiple
     * times.  This block may (1) just be traversed without
     * side effects, (2) `break` on resource errors or
     * (3) `continue`, calling advance_wkl_state() to skip
     * if this suspension is not applicable to this answer
     * instance.
     */

    if ( sp->instance && an )
    { int rc;

      if ( !state->keys_inited )
      { Word p = valTermRef(A2);
	Functor f;
	size_t arity, i;

	deRef(p);
	assert(isTerm(*p));
	f = valueTerm(*p);
	arity = arityFunctor(f->definition);

	if ( arity > SINDEX_MAX )
	  arity = SINDEX_MAX;

	for(i=0; i<arity; i++)
	  state->keys[i].key = (unsigned int)index_of_word(f->arguments[i]);

	state->keys_inited = true;
      }

      const sindex_key *skeys = state->keys;
      skeys--;					/* key args are one based */

      for(;;)
      { if ( unlikely((suspension_matches_index(sp, skeys))) )
	{ rc = suspension_matches(A2, sp);

	  if ( rc == true )  goto match;
	  if ( rc != false ) goto out_fail;
	}

	if ( likely((sp = --state->suspensions.here) >= state->suspensions.base) )
	{ if ( unlikely(!sp->instance) )
	    goto match;
	} else
	{ goto next;
	}
      }
    }

    /* Found real work to do.  If we get here we can only fail due to
     * resource errors.  Normally we succeed with or without a choice
     * point.
     */

  match:
    if ( !( (susp=PL_new_term_ref()) &&
	    PL_recorded(UNTNOT(sp->term), susp) &&
				      /* unifies A4..A8 */
	    unify_dependency(A2, susp, state->list, an)
	  ) )
      break;			/* resource errors */

    DEBUG(MSG_TABLING_WORK,
	  { Sdprintf("Work: %d %d\n\t",
		     (int)state->acp_index,
		     (int)(state->suspensions.here - state->suspensions.base));
	    PL_write_term(Serror, A2, 1200, PL_WRT_NEWLINE);
	    Sdprintf("\t");
	    PL_write_term(Serror, susp, 1200, PL_WRT_NEWLINE);
	  });

    if ( advance_wkl_state(state) )
    { ForeignRedoPtr(state);
    } else
    { free_wkl_state(state);
      return true;
    }
  next:
    ;
  } while ( advance_wkl_state(state) );

out_fail:
  free_wkl_state(state);
  return false;
}


/** '$tbl_variant_table'(+Closure, +Variant, -Trie, -Status,
 *			 -Skeleton, -IsMono) is det.
 *
 * Retrieve the table for Variant. Status is one of
 *
 *   - `fresh` if the table is new
 *   - `complete` if the table is completed
 *   - A worklist pointer
 */

#define tbl_variant_table(closure, variant, Trie, abstract,	    \
			  status, ret, is_monotonic, flags)	    \
	LDFUNC(tbl_variant_table, closure, variant, Trie, abstract, \
	       status, ret, is_monotonic, flags)

static bool
tbl_variant_table(DECL_LD term_t closure, term_t variant, term_t Trie,
		  term_t abstract, term_t status, term_t ret,
		  term_t is_monotonic, int flags)
{ trie *atrie;
  Definition def = NULL;
  atom_t clref = 0;

  get_closure_predicate(closure, &def);

  if ( (atrie=get_answer_table(def, variant, ret, &clref, flags)) )
  { if ( !idg_init_variant(atrie, def, variant)  ||
	 !idg_add_edge(atrie, NULL) )
      return false;

    if ( is_monotonic &&
	 def->tabling && ison(def->tabling, TP_MONOTONIC) &&
	 ( LD->tabling.in_assert_propagation ||
	   inner_is_monotonic() ) )
    { assert(ison(environment_frame, FR_INRESET));
      if ( !PL_unify_bool(is_monotonic, true) )
	return false;
    }

    if ( clref )
    { TRIE_STAT_INC(atrie, gen_call);
      return ( PL_unify_atomic(Trie, clref) &&
	       PL_unify_atomic(status, ATOM_complete) );
    } else
    { return ( PL_unify_atomic(Trie, atrie->symbol) &&
	       unify_table_status(status, atrie, def, true) );
    }
  }

  return false;
}

static
PRED_IMPL("$tbl_variant_table", 6, tbl_variant_table, 0)
{ PRED_LD

  bool rc = tbl_variant_table(A1, A2, A3, 0, A4, A5, A6,
			      AT_CREATE);
  DEBUG(CHK_SECURE, checkStacks(NULL));
  return rc;
}


/** '$tbl_abstract_table'(+Closure, :Wrapper, -Trie,
			  -Abstract, -Status, -Skeleton)

Abstract is one of `0` or a generalization of Wrapper
*/

static
PRED_IMPL("$tbl_abstract_table", 6, tbl_abstract_table, 0)
{ PRED_LD

  return tbl_variant_table(A1, A2, A3, A4, A5, A6, 0,
			   AT_CREATE|AT_ABSTRACT);
}


static
PRED_IMPL("$tbl_moded_variant_table", 6, tbl_moded_variant_table, 0)
{ PRED_LD

  return tbl_variant_table(A1, A2, A3, 0, A4, A5, A6,
			   AT_CREATE|AT_MODED);
}


static
PRED_IMPL("$tbl_existing_variant_table", 5, tbl_existing_variant_table, 0)
{ PRED_LD
  trie *trie;
  Definition def = NULL;
  atom_t clref = 0;

  get_closure_predicate(A1, &def);

  if ( (trie=get_answer_table(def, A2, A5, &clref, false)) )
  { return ( PL_unify_atomic(A3, trie->symbol) &&
	     unify_table_status(A4, trie, def, true) );
  }

  return false;
}


static
PRED_IMPL("$tbl_local_variant_table", 1, tbl_local_variant_table, 0)
{ PRED_LD
  trie *trie = LD->tabling.variant_table;

  if ( trie )
    return PL_unify_atomic(A1, trie->symbol);

  return false;
}


static
PRED_IMPL("$tbl_global_variant_table", 1, tbl_global_variant_table, 0)
{
#ifdef O_PLMT
  PRED_LD
  trie *trie = GD->tabling.variant_table;

  if ( trie )
    return PL_unify_atomic(A1, trie->symbol);
#endif

  return false;
}


/** '$tbl_variant_table'(?Table) is nondet.
 *
 *  True when Table is a variant table. If there is both a local and
 *  global table it first returns the local one and then the global one.
 *  '$tbl_local_variant_table'/1 and '$tbl_global_variant_table'/1 fetch
 *  a specific table.
 *
 *  This predicate is in C to make it easy to be deterministic in case
 *  there is no global table.
 */

#ifdef O_PLMT
static
PRED_IMPL("$tbl_variant_table", 1, tbl_variant_table, PL_FA_NONDETERMINISTIC)
{ PRED_LD
  trie *trie;

  switch( CTX_CNTRL )
  { case FRG_FIRST_CALL:
      if ( (trie=LD->tabling.variant_table) )
      { if ( PL_unify_atomic(A1, trie->symbol) )
	{ if ( GD->tabling.variant_table )
	    ForeignRedoInt(1);
	  else
	    return true;
	}
      }
    /*FALLTHROUGH*/
    case FRG_REDO:
      if ( (trie=GD->tabling.variant_table) )
	return PL_unify_atomic(A1, trie->symbol);
      return false;
    case FRG_CUTTED:
      return true;
	default:
      assert(0);
      return false;
  }
}
#endif

/** '$tbl_table_status'(+Trie, -Status)
 *
 * Get the status of an answer table.
 */

static
PRED_IMPL("$tbl_table_status", 2, tbl_table_status, 0)
{ PRED_LD
  trie *trie;

  return ( get_trie(A1, &trie) &&
	   unify_table_status(A2, trie, NULL, false)
	 );
}


/** '$tbl_table_status'(+Trie, -Status, -Wrapper, -Skeleton)
 *
 * Get the status of Trie as well as its wrapper and Skeleton.
 */

static
PRED_IMPL("$tbl_table_status", 4, tbl_table_status, 0)
{ PRED_LD
  trie *trie;
  term_t wv = PL_new_term_ref();

  return ( get_trie(A1, &trie) &&
	   unify_table_status(A2, trie, NULL, false) &&
	   unify_skeleton(trie, wv, A4) &&
	   PL_unify(A3, wv)
	 );
}


/** '$tbl_table_pi'(+ATrie, -PredicateIndicator)
 *
 * Get the predicate indicator that is associated with an answer trie.
 * This is used for e.g., abstracting the IDG to predicates.
 */

static
PRED_IMPL("$tbl_table_pi", 2, tbl_table_pi, 0)
{ PRED_LD
  trie *atrie;

  if ( get_trie(A1, &atrie) )
  { term_t av = PL_new_term_refs(3);
    term_t wrapper = av+0;
    term_t module  = av+1;
    term_t head	   = av+2;

    if ( unify_trie_term(atrie->data.variant, NULL, wrapper) )
    { atom_t name;
      size_t arity;

      assert(PL_is_functor(wrapper, FUNCTOR_colon2));
      _PL_get_arg(1, wrapper, module);
      _PL_get_arg(2, wrapper, head);
      if ( PL_get_name_arity(head, &name, &arity) )
      { return PL_unify_term(A2, PL_FUNCTOR, FUNCTOR_colon2,
				   PL_TERM, module,
				   PL_FUNCTOR, FUNCTOR_divide2,
				     PL_ATOM, name,
				     PL_INTPTR, (intptr_t)arity);
      }
    }
  }

  return false;
}


/* - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - -
Finish re-evaluation of a component by  running reeval_complete() on all
re-evaluated answer tables. Typically either none   of the answer tables
is a re-evaluated one or all are.  In   some  cases though, there may be
some non-reevaluated tables, either because the   table was abolished or
because a new table gets involved into the SCC.

We could maintain a flag on the   SCC telling re-evaluated tables may be
involved. Not sure it is worth while.
- - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - */

static void
wls_reeval_complete(worklist **wls, size_t ntables)
{ size_t i;
  size_t reevaluated = 0;

  for(i=0; i<ntables; i++)
  { worklist *wl = wls[i];
    trie *atrie = wl->table;
    idg_node *n;

    if ( (n=atrie->data.IDG) )
    { if ( n->reevaluating )
      { reeval_complete(atrie);
	reevaluated++;
      }
    }
  }

  if ( reevaluated )
  { for(i=0; i<ntables; i++)
    { worklist *wl = wls[i];
      trie *atrie = wl->table;
      idg_node *n;

      if ( (n=atrie->data.IDG) )
      { n->reevaluating = false;
	assert(n->falsecount == 0);
      }
    }
  }
}


#define unify_leader_clause(scc, cl) LDFUNC(unify_leader_clause, scc, cl)
static int
unify_leader_clause(DECL_LD tbl_component *scc, term_t cl)
{ trie *atrie = scc->leader;
  Procedure proc = (ison(atrie, TRIE_ISMAP)
			     ? GD->procedures.trie_gen_compiled3
			     : GD->procedures.trie_gen_compiled2);
  atom_t clref = compile_trie(proc->definition, atrie);

  TRIE_STAT_INC(atrie, gen_call);
  return PL_unify_atomic(cl, clref);
}


/** '$tbl_table_complete_all'(+SCC, -Status, -Clause)
 *
 * Complete and reset all newly created tables.
 *
 * (*) currently we keep worklists that play a role on a network
 * of undefined answers.  That is needed for lazy answer completion
 * (see O_AC_EAGER).  If we do not do so, we still must keep track
 * of dependencies when abolishing tries.
 */

static
PRED_IMPL("$tbl_table_complete_all", 3, tbl_table_complete_all, 0)
{ PRED_LD
  tbl_component *c;

  if ( !get_scc(A1, &c) )
    return false;

  if ( c->status == SCC_ACTIVE )
  { worklist **wls;
    size_t ntables = worklist_set_to_array(c->created_worklists, &wls);
    size_t i;
    int rc;

    wls_reeval_complete(wls, ntables);
    rc = unify_leader_clause(c, A3);

    for(i=0; i<ntables; i++)
    { worklist *wl = wls[i];
      trie *atrie = wl->table;

      DEBUG(MSG_TABLING_WORK,
	    { term_t t = PL_new_term_ref();
	      unify_trie_term(atrie->data.variant, NULL, t);
	      Sdprintf("Setting wl %zd in scc %zd to COMPLETE.  Variant: ",
		       pointerToInt(wl), pointerToInt(c));
	      PL_write_term(Serror, t, 999, PL_WRT_NEWLINE);
	    });

      if ( ison(atrie, TRIE_ABOLISH_ON_COMPLETE) )
      { atrie->data.worklist = NULL;
	wl->table = NULL;
	destroy_answer_trie(atrie);
	free_worklist(wl);
      } else
      { int destroy = !wl->undefined && isEmptyBuffer(&wl->delays); /* see (*) */

	complete_worklist(wl, destroy);
      }
    }
    reset_newly_created_worklists(c, WLFS_FREE_NONE);
    c->status = SCC_COMPLETED;

    if ( c->parent && LD->tabling.component == c )
      LD->tabling.component = c->parent;
    if ( !c->parent )
      LD->tabling.has_scheduling_component = false;

    if ( !rc )
      return false;
  }

  return unify_component_status(A2, c);
}


/** '$tbl_free_component'(+SCC)
 *
 * Destroy a component and all subcomponents
 */

static
PRED_IMPL("$tbl_free_component", 1, tbl_free_component, 0)
{ PRED_LD
  tbl_component *c;

  if ( get_scc(A1, &c) )
  { assert(!c->parent);
    if ( LD->tabling.component == c )
      free_component(c, FC_DESTROY);
    assert(LD->tabling.component == NULL);
    return true;
  }

  return false;
}


/** '$tbl_table_discard_all'(+SCC)
 *
 * Discard all newly created tables and the worklists. This is used if
 * an exception happens during tabling.
 */

static
PRED_IMPL("$tbl_table_discard_all", 1, tbl_table_discard_all, 0)
{ PRED_LD
  tbl_component *c;

  if ( get_scc(A1, &c) )
  { if ( c->status != SCC_MERGED )
    { tbl_component *parent = c->parent;

      if ( c->created_worklists )
	reset_newly_created_worklists(c, WLFS_DISCARD_INCOMPLETE);
      reset_global_worklist(c);

      LD->tabling.component = parent;
      free_component(c, FC_DESTROY);

      if ( !parent )
	LD->tabling.has_scheduling_component = false;
    }
  }

  return true;
}


static tbl_component *
tbl_create_subcomponent(DECL_LD trie *leader)
{ if ( !LD->tabling.has_scheduling_component )
  { LD->tabling.has_scheduling_component = true;
    if ( !LD->tabling.component || LD->tabling.in_answer_completion )
      LD->tabling.component = new_component();
    else
      LD->tabling.component->status = SCC_ACTIVE;
    LD->tabling.component->leader = leader;
  } else
  { tbl_component *c = new_component();
    tbl_component *p;

    c->leader = leader;
    c->parent = (p=LD->tabling.component);
    LD->tabling.component = c;
    add_child_component(p, c);
  }

  return LD->tabling.component;
}


static int
unify_component_status(DECL_LD term_t t, tbl_component *scc)
{ atom_t status;

  switch(scc->status)
  { case SCC_ACTIVE:	status = ATOM_active; break;
    case SCC_MERGED:	status = ATOM_merged; break;
    case SCC_COMPLETED:
    { if ( scc->parent )
	status = ATOM_complete;
      else
	status = ATOM_final;
      break;
    }
    default:
      assert(0);
      return false;
  }

  return PL_unify_atom(t, status);
}

/** '$tbl_abolish_local_tables' is det.
 *
 * Clear the thread table data.  Fails silently if tabling is in
 * progress.
 */

static
PRED_IMPL("$tbl_abolish_local_tables", 0, tbl_abolish_local_tables, 0)
{ PRED_LD

  if ( !LD->tabling.has_scheduling_component )
  { clearThreadTablingData(LD);
    return true;
  }

  return false;
}

/** '$tbl_trienode'(-X) is det.
 *
 * X is the reserved node value for non-moded arguments.
 */

static
PRED_IMPL("$tbl_trienode", 1, tbl_trienode, 0)
{ PRED_LD

  return PL_unify_atom(A1, ATOM_trienode);
}

/** '$tbl_is_trienode'(@X) is det.
 *
 * True if X is the reserved trie node.
 */

static
PRED_IMPL("$tbl_is_trienode", 1, tbl_is_trienode, 0)
{ PRED_LD
  Word p = valTermRef(A1);

  deRef(p);
  return *p == ATOM_trienode;
}

		 /*******************************
		 *     INSPECT TABLING DATA	*
		 *******************************/

static
PRED_IMPL("$tbl_scc", 1, tbl_scc, 0)
{ PRED_LD

  if ( LD->tabling.component )
    return PL_unify_pointer(A1, LD->tabling.component);

  return false;
}

static int
unify_wl_set(term_t l, worklist_set *wls)
{ GET_LD
  worklist **p;
  size_t i, n = worklist_set_to_array(wls, &p);

  term_t tail = PL_copy_term_ref(l);
  term_t head = PL_new_term_ref();
  for(i=0; i<n; i++)
  { if ( !PL_unify_list(tail, head, tail) ||
	 !PL_unify_pointer(head, p[i]) )
      return false;
  }

  return PL_unify_nil(tail);
}

static int
unify_scc_set(term_t l, component_set *cs)
{ GET_LD
  term_t tail = PL_copy_term_ref(l);

  if ( cs )
  { tbl_component **c = baseBuffer(&cs->members, tbl_component*);
    tbl_component **top = topBuffer(&cs->members, tbl_component*);
    term_t head = PL_new_term_ref();

    for(; c < top; c++)
    { if ( !PL_unify_list(tail, head, tail) ||
	   !PL_unify_pointer(head, *c) )
	return false;
    }
  }

  return PL_unify_nil(tail);
}

static int
unify_pointer_or_nil(term_t t, void *ptr)
{ GET_LD

  if ( ptr )
    return PL_unify_pointer(t, ptr);
  else
    return PL_unify_atom_chars(t, "null");
}

static
PRED_IMPL("$tbl_scc_data", 2, tbl_scc_data, 0)
{ PRED_LD
  tbl_component *scc;

  if ( get_scc(A1, &scc) )
  { term_t av = PL_new_term_refs(5);
    term_t t = PL_new_term_ref();

    return ( unify_pointer_or_nil(av+0, scc->parent) &&
	     unify_scc_set(av+1, scc->children) &&
	     unify_component_status(av+2, scc) &&
	     unify_wl_set(av+3, scc->worklist) &&
	     unify_wl_set(av+4, scc->created_worklists) &&
	     PL_cons_functor_v(t, FUNCTOR_scc5, av) &&
	     PL_unify(t, A2) );
  }

  return false;
}


static int
unify_cluster(term_t t, cluster *c, int is_riac)
{ GET_LD

  if ( is_riac )
  { term_t a = PL_new_term_ref();
    if ( !PL_unify_term(t, PL_FUNCTOR_CHARS, "riac", 1,
			     PL_TERM, a) )
      return false;
    t = a;
  }

  term_t tail = PL_copy_term_ref(t);
  term_t head = PL_new_term_ref();

  if ( c->type == CLUSTER_ANSWERS )
  { trie_node **ap  = baseBuffer(&c->members, trie_node*);
    trie_node **top = topBuffer(&c->members, trie_node*);

    for(; ap < top; ap++)
    { trie_node *an = *ap;

      if ( !PL_unify_list(tail, head, tail) ||
	   !tbl_unify_answer(an, head)  )
	return false;
    }
    return PL_unify_nil(tail);
  } else
  { suspension *sp  = baseBuffer(&c->members, suspension);
    suspension *top = topBuffer(&c->members, suspension);
    term_t tmp = PL_new_term_ref();

    assert(c->type == CLUSTER_SUSPENSIONS);

    for(; sp < top; sp++)
    { if ( !PL_unify_list(tail, head, tail) ||
	   !PL_recorded(UNTNOT(sp->term), tmp) ||
	   !PL_unify(tmp, head) )
	return false;
    }
    return PL_unify_nil(tail);
  }
}


static int
unify_clusters(term_t t, worklist *wl)
{ GET_LD
  cluster *c;
  term_t tail = PL_copy_term_ref(t);
  term_t head = PL_new_term_ref();

  for(c=wl->head; c; c=c->next)
  { if ( !PL_unify_list(tail, head, tail) ||
	 !unify_cluster(head, c, c==wl->riac) )
      return false;
  }

  return PL_unify_nil(tail);
}


static
PRED_IMPL("$tbl_worklist_data", 2, tbl_worklist_data, 0)
{ PRED_LD
  worklist *wl;

  if ( get_worklist(A1, &wl) )
  { term_t av = PL_new_term_refs(5);
    term_t t = PL_new_term_ref();

    return ( PL_unify_pointer(av+0, wl->component) &&
	     PL_unify_atomic(av+1, wl->table->symbol) &&
	     PL_unify_bool(av+2, wl->in_global_wl) &&
	     PL_unify_bool(av+3, wl->executing) &&
	     unify_clusters(av+4, wl) &&
	     PL_cons_functor_v(t, FUNCTOR_worklist5, av) &&
	     PL_unify(t, A2)
	   );
  }

  return false;
}


static
PRED_IMPL("$tbl_wkl_table", 2, tbl_wkl_table, 0)
{ PRED_LD
  worklist *wl;

  return ( get_worklist(A1, &wl) &&
	   PL_unify_atomic(A2, wl->table->symbol) );
}


typedef struct
{ term_t skel;
} answer_ctx;

/** '$tbl_answer'(+Trie, -Answer, -Condition) is nondet.
 */

#define put_delay_set(cond, di, set, ctx) \
	LDFUNC(put_delay_set, cond, di, set, ctx)

static bool
put_delay_set(DECL_LD term_t cond, delay_info *di, delay_set *set,
	      answer_ctx *ctx)
{ delay *base, *top;
  term_t av = PL_new_term_refs(6);
  int count = 0;
  term_t gshare = 0;
  term_t gskel  = 0;
  size_t arity  = 0;
  term_t tmp    = av+4;
  term_t ret    = av+5;

  get_delay_set(di, set, &base, &top);

  /* Get the variable sharing term */
  if ( top > base && top[-1].answer && !top[-1].variant )
  { record_t r;

    assert(IS_REC_DELAY(top[-1].answer));
    r = UNREC_DELAY(top[-1].answer);
    if ( !(gshare = PL_new_term_refs(2)) ||
	 !PL_recorded(r, gshare) )
      return false;
    PL_get_name_arity(gshare, NULL, &arity);
    gskel = gshare+1;
    _PL_get_arg(1, gshare, gskel);
    if ( !PL_unify(gskel, ctx->skel) )
    { DEBUG(0, Sdprintf("Oops, global skeleton doesn't unify\n"));
      return false;
    }

    top--;

    DEBUG(MSG_TABLING_DELAY_VAR,
	  { Sdprintf("Got sharing skeleton of size %zd\n", arity);
	    pl_writeln(gshare);
	  });
  }

  for(--top; top >= base; top--)
  { term_t c1 = count == 0 ? cond : av+0;

    if ( top->variant == DV_DELETED )
    { if ( top->answer && !is_ground_trie_node(top->answer) )
	arity--;
      continue;
    }
    if ( top->answer )				/* positive delay */
    { term_t ans  = av+1;
      term_t uans;

      PL_put_variable(c1);
      PL_put_variable(ans);
      PL_put_variable(ret);

      if ( !unify_trie_term(top->variant->data.variant, NULL, c1) )
	return false;
      if ( !get_answer_table(NULL, c1, ret, NULL, false) )
      { Sdprintf("OOPS! could not find variant table\n");
	return false;
      }

      if ( ison(top->answer, TN_SECONDARY) ) /* Ret/ModeArgs */
      { if ( !tbl_unify_answer(top->answer, ans) ||
	     !PL_get_arg(1, ans, tmp) ||
	     !PL_unify(tmp, ret) ||
	     !PL_get_arg(2, ans, tmp) ||
	     !PL_cons_functor(c1, FUNCTOR_divide2, c1, tmp) )
	  return false;
	uans = ans;
      } else
      { if ( !unify_trie_term(top->answer, NULL, ret) )
	  return false;
	uans = ret;
      }

      if ( !is_ground_trie_node(top->answer) )
      { assert(gshare);

	_PL_get_arg(arity, gshare, gskel);
	if ( !PL_unify(gskel, uans) )
	{ DEBUG(0, Sdprintf("Oops, skeleton %zd does not unify\n", arity));
	  pl_writeln(gskel);
	  pl_writeln(ans);
	  return false;
	}
	arity--;
      }
    } else					/* negative delay */
    { PL_put_variable(c1);
      if ( !unify_trie_term(top->variant->data.variant, NULL, c1) ||
	   !PL_cons_functor(c1, FUNCTOR_tnot1, c1) )
	return false;
    }

    if ( count++ > 0 )
    { if ( !PL_cons_functor(cond, FUNCTOR_comma2, c1, cond) )
	return false;
    }
  }

  PL_reset_term_refs(av);

  return true;
}

#define unify_delay_info(t, answer, ctxp) \
	LDFUNC(unify_delay_info, t, answer, ctxp)

static bool
unify_delay_info(DECL_LD term_t t, trie_node *answer, void *ctxp)
{ delay_info *di;

  if ( (di=answer_delay_info(NULL, answer, false)) )
  { if ( DL_IS_DELAY_LIST(di) )
    { term_t av = PL_new_term_refs(2);
      term_t cond = av+1;
      delay_set *base, *top;
      int count = 0;
      answer_ctx *ctx = ctxp;

      delay_sets(di, &base, &top);
      for(; base < top; base++)
      { term_t c1 = count == 0 ? cond : av+0;

	if ( isEmptyBuffer(&di->delay_sets) )
	  continue;

	if ( !put_delay_set(c1, di, base, ctx) )
	  return false;

	if ( count++ > 0 )
	{ if ( !PL_cons_functor_v(cond, FUNCTOR_semicolon2, av) )
	    return false;
	}
      }

      return PL_unify(t, cond);
    } else
    { return PL_unify_atom(t, ATOM_undefined);
    }
  } else
  { return PL_unify_atom(t, ATOM_true);
  }
}

#if O_DEBUG
static bool
put_delay_info(term_t t, trie_node *answer)
{ GET_LD
  answer_ctx ctx;

  return ( (ctx.skel = PL_new_term_ref()) &&
	   PL_put_variable(t) &&
	   unify_delay_info(t, answer, &ctx) );
}
#endif

/** '$tbl_answer'(+Trie, ?Skeleton, -Condition) is nondet.
 */

static
PRED_IMPL("$tbl_answer", 3, tbl_answer, PL_FA_NONDETERMINISTIC)
{ answer_ctx ctx;

  ctx.skel = A2;
  return trie_gen(A1, 0, A2, 0, A3, unify_delay_info, &ctx, PL__ctx);
}

/** '$tbl_answer_c'(+Trie, +Skeleton, -ModedArgs, -Condition) is nondet.
 */

static
PRED_IMPL("$tbl_answer_c", 4, tbl_answer_c, PL_FA_NONDETERMINISTIC)
{ PRED_LD
  trie *trie;

  if ( CTX_CNTRL == FRG_CUTTED )
    return clear_trie_gen_state(CTX_PTR);

  if ( get_trie(A1, &trie) )
  { Word kp;
    trie_node *root;
    int rc;

    kp = valTermRef(A2);
    rc = trie_lookup(trie, NULL, &root, kp, false, NULL);
    if ( rc == true )
    { answer_ctx ctx;

      ctx.skel = A2;
      return trie_gen_raw(trie, root, A3, 0, A4, unify_delay_info, &ctx, PL__ctx);
    } else
    { rc = trie_error(rc, A1);
    }

    return rc;
  }

  return false;
}


#define unify_delay_info_dl(t, answer, ctx) \
	LDFUNC(unify_delay_info_dl, t, answer, ctx)

static bool
unify_delay_info_dl(DECL_LD term_t t, trie_node *answer, void *ctx)
{ (void) ctx;

  if ( (answer->flags & (TN_IDG_DELETED|TN_IDG_ADDED)) == TN_IDG_DELETED )
    return false;

  if ( answer_is_conditional(answer) )
  { if ( is_ground_trie_node(answer) )
      return PL_unify_pointer(t, answer);
    else
      return PL_unify_atom(t, ATOM_nonground);
  } else
  { return PL_unify_atom(t, ATOM_true);
  }
}

static
PRED_IMPL("$tbl_answer_dl", 3, tbl_answer_dl, PL_FA_NONDETERMINISTIC)
{ return trie_gen(A1, 0, A2, 0, A3, unify_delay_info_dl, NULL, PL__ctx);
}

/** '$tbl_answer_dl'(+ATrie, +Skeleton, -Sumbsuming, -DL) is nondet.
*/

static
PRED_IMPL("$tbl_answer_dl", 4, tbl_answer_dl, PL_FA_NONDETERMINISTIC)
{ PRED_LD
  trie *trie;

  if ( CTX_CNTRL == FRG_CUTTED )
    return clear_trie_gen_state(CTX_PTR);

  if ( get_trie(A1, &trie) )
  { Word kp;
    trie_node *root;
    int rc;

    kp = valTermRef(A2);
    rc = trie_lookup(trie, NULL, &root, kp, false, NULL);
    if ( rc == true )
    { return trie_gen_raw(trie, root, A3, 0, A4, unify_delay_info_dl,
			  NULL, PL__ctx);
    } else
    { rc = trie_error(rc, A1);
    }

    return rc;
  }

  return false;
}


/** '$tbl_answer_update_dl'(+ATrie, -Skeleton) is nondet.
 *
 * Obtain an answer from ATrie.  If the answer is conditional, update
 * the global delay list.  If the answer is ground with a term
 * ATrie+ANode and otherwise ATrie+Wrapper
 */

typedef struct
{ term_t atrie;
} update_dl_ctx;

#define answer_update_delay_list(wrapper, answer, vctx) \
	LDFUNC(answer_update_delay_list, wrapper, answer, vctx)

static bool
answer_update_delay_list(DECL_LD term_t wrapper, trie_node *answer, void *vctx)
{ update_dl_ctx *ctx = vctx;

  if ( answer_is_conditional(answer) )
  { Word p;

    if ( !ensureStackSpace(10, 2) )
      return false;
    p = valTermRef(ctx->atrie);
    deRef(p);
    assert(isAtom(*p));

    tbl_push_delay(word2atom(*p), valTermRef(wrapper), answer);
  }

  return true;
}

static
PRED_IMPL("$tbl_answer_update_dl", 2, tbl_answer_update_dl,
	  PL_FA_NONDETERMINISTIC)
{ update_dl_ctx ctx;

  ctx.atrie = A1;

  return trie_gen(A1, 0, A2, 0, A2, answer_update_delay_list, &ctx, PL__ctx);
}


/** '$tbl_answer_update_dl'(+Trie, +Skeleton, -ModeArgs) is nondet.
*/

static
PRED_IMPL("$tbl_answer_update_dl", 3, tbl_answer_update_dl,
	  PL_FA_NONDETERMINISTIC)
{ PRED_LD
  trie *trie;

  if ( CTX_CNTRL == FRG_CUTTED )
    return clear_trie_gen_state(CTX_PTR);

  if ( get_trie(A1, &trie) )
  { Word kp;
    trie_node *root;
    int rc;

    kp = valTermRef(A2);
    rc = trie_lookup(trie, NULL, &root, kp, false, NULL);
    if ( rc == true )
    { update_dl_ctx ctx;

      ctx.atrie = A1;
      return trie_gen_raw(trie, root, A3, 0, A3,
			  answer_update_delay_list, &ctx, PL__ctx);
    } else
    { rc = trie_error(rc, A1);
    }

    return rc;
  }

  return false;
}


/** '$tbl_implementation'(:G0, -G) is det.
 *
 * Find location where G is actually defined and raise an error of the
 * predicate is not tabled.
 */

static int
is_tabled(Definition def)
{ table_props *props;

  return (props=def->tabling) && ison(props, TP_TABLED);
}


#define tbl_implementation(g0, g, must_be_tabled) LDFUNC(tbl_implementation, g0, g, must_be_tabled)
static int
tbl_implementation(DECL_LD term_t g0, term_t g, int must_be_tabled)
{ Module m = NULL;
  term_t t = PL_new_term_ref();
  functor_t f = 0;
  Procedure proc;
  Definition def;

  if ( !PL_strip_module(g0, &m, t) )
    return false;
  if ( !PL_get_functor(t, &f) )
    return PL_type_error("callable", g0);
  if ( !(proc = resolveProcedure(f, m)) )
    return false;				/* should not happen */

  if ( !isDefinedProcedure(proc) )
    trapUndefined(getProcDefinition(proc));
  def = getProcDefinition(proc);

  if ( must_be_tabled && !is_tabled(def) )
  { return PL_error(NULL, 0, NULL, ERR_PERMISSION_PROC,
		    ATOM_tnot, ATOM_non_tabled_procedure, proc);
  }

  if ( def->module == m )
  { return PL_unify(g, g0);
  } else
  { return PL_unify_term(g, PL_FUNCTOR, FUNCTOR_colon2,
			      PL_ATOM, def->module->name,
			      PL_TERM, t);
  }
}


static
PRED_IMPL("$tnot_implementation", 2, tnot_implementation, PL_FA_TRANSPARENT)
{ PRED_LD

  return tbl_implementation(A1, A2, true);
}

static
PRED_IMPL("$tbl_implementation", 2, tbl_implementation, PL_FA_TRANSPARENT)
{ PRED_LD

  return tbl_implementation(A1, A2, false);
}

/**
 * '$is_answer_trie'(@Trie, -Type) is semidet
 *
 * True if Trie is an answer trie, possible already destroyed.  Type
 * is one of
 *
 *   - dynamic
 *   - monotonic(How)
 *     How is one of `lazy` or `eager`
 *   - incremental
 *   - normal
 */

static
PRED_IMPL("$is_answer_trie", 2, is_answer_trie, 0)
{ PRED_LD
  trie *atrie;

  if ( get_trie_noex(A1, &atrie) &&
       atrie->release_node == release_answer_node )
  { idg_node *n;

    if ( atrie->data.worklist == WL_DYNAMIC )
    { return PL_unify_atom(A2, ATOM_dynamic);
    } else if ( (n=atrie->data.IDG) )
    { if ( n->monotonic )
	return PL_unify_term(A2, PL_FUNCTOR, FUNCTOR_monotonic1, PL_ATOM, n->lazy ? ATOM_lazy : ATOM_eager);

      return PL_unify_atom(A2, ATOM_incremental);
    } else
    { return PL_unify_atom(A2, ATOM_normal);
    }
  }

  return false;
}




		 /*******************************
		 *     TRANSACTION SUPPORT	*
		 *******************************/

/* - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - -
True when `atrie` is an incremental or  monotonic table, we are inside a
transaction and one of the dependent predicates has been modified inside
the transaction. If this is the case we   must invalidate the table on a
rollback of the transaction.  More precisely:

  - For an incremental table we need to invalidate iff
    - For a fresh table the initial evaluation depends on modified
      dynamic predicates
    - For a revaluated table it depends on modified predicates either
      at the start of the reevaluation or the end.
- - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - */

static int
tt_has_modified_dependencies(DECL_LD trie *atrie)
{ idg_node *n;
  int found = false;

  if ( (n=atrie->data.IDG) &&
       LD->transaction.predicates )
  { TablePP deps;

    if ( (deps=n->dependent) )
    { FOR_TABLE(deps, n, v)
      { idg_node *dep = key2ptr(n);
	trie *strie = dep->atrie;

	if ( strie->data.worklist == WL_DYNAMIC &&
	     lookupHTablePW(LD->transaction.predicates,
			    strie->data.predicate) )
	{ found = true;
	  break;
	}
      }
    }
  }

  return found;
}


/* - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - -
tt_mono_status(DECL_LD trie *atrie) figures out how   to deal with a lazy
monotonic table that is  being  reevaluated.   It  is  called before the
reevaluation happens and examines the table status:

  - If any of the dependent _tables_ is invalid, mark the table to
    be invalidated.  Normally lazy monotonic tables reevaluation
    starts at the leafs and an invalid dependent table thus indicates
    a cycle.  Possibly there are scenarios where we can do better.
  - Example the the queued clauses from dynamic dependencies and
    - If all are older than the transaction, revaluate without
      trailing.
    - If all are from the transaction, trail the answers
    - If there is a mix, mark for invalidation.  Again, it might
      be possible to do better.  It is hard to tell whether an
      answer is due to a new clause or due to an old one.

This is called from '$mono_reeval_prepare'/2
- - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - */

typedef struct
{ size_t invalid_dep_tables;
  size_t global_clauses;
  size_t local_clauses;
} mono_dep_status;


#define lg_clauses(mdep, s) LDFUNC(lg_clauses, mdep, s)
static void
lg_clauses(DECL_LD idg_mdep *mdep, mono_dep_status *s)
{ if ( mdep->queue )
  { word *base = baseBuffer(mdep->queue, word);
    word *top  = topBuffer(mdep->queue, word);

    for(; base < top; base++)
    { if ( isAtom(*base) )
      { ClauseRef cref = clause_clref(word2atom(*base));
	Clause cl = cref->value.clause;

	if ( !ison(cl, CL_ERASED) )
	{ if ( cl->generation.created < GEN_TRANSACTION_BASE )
	    s->global_clauses++;
	  else if ( cl->generation.created >= LD->transaction.gen_base &&
		    cl->generation.created <  LD->transaction.gen_max )
	    s->local_clauses++;
	}
      } else
      { assert(0);
      }
    }
  }
}

typedef enum
{ M_INVALID_DEPS,
  M_OLD_CLAUSES,
  M_MIXED_CLAUSES,
  M_NEW_CLAUSES			/* also none of the above */
} mono_status;

#define tt_mono_status(atrie) LDFUNC(tt_mono_status, atrie)
static mono_status
tt_mono_status(DECL_LD trie *atrie)
{ idg_node *an;
  mono_dep_status status = {0};

  if ( (an=atrie->data.IDG) )
  { TablePP deps;

    DEBUG(MSG_TABLING_TRANSACTION,
	  print_answer_table(atrie, "tt_mono_status()"));

    if ( (deps=an->dependent) )
    { FOR_TABLE(deps, dn, v)
      { idg_node *dep = key2ptr(dn);
	trie *strie = (trie *)dep->atrie;

	if ( strie->data.worklist == WL_DYNAMIC )
	{ idg_mdep *mdep;

	  DEBUG(MSG_TABLING_TRANSACTION,
		print_answer_table(strie, "Dynamic dependency"));

	  if ( (mdep=lookupHTablePP(dep->affected, an)) )
	    lg_clauses(mdep, &status);
	} else
	{ if ( dep->falsecount > 0 ||
	       dep->force_reeval )
	    status.invalid_dep_tables++;
	}

	if ( status.invalid_dep_tables )
	  break;
      };
    }
  }

  if ( status.invalid_dep_tables )
    return M_INVALID_DEPS;
  else if ( status.global_clauses && status.local_clauses )
    return M_MIXED_CLAUSES;
  else
    return status.global_clauses ? M_OLD_CLAUSES : M_NEW_CLAUSES;
}




static void
tt_free_table_symbol(table_key_t k, table_value_t v)
{ atom_t symbol = (atom_t)k;
  (void)v;

  PL_unregister_atom(symbol);
}


#define tt_trail(_) LDFUNC(tt_trail, _)
static tbl_trail *
tt_trail(DECL_LD)
{ tbl_trail *tt;

  if ( unlikely(!(tt=LD->transaction.table_trail)) )
  { tt = allocHeapOrHalt(sizeof(*tt));
    memset(tt, 0, sizeof(*tt));
    initBuffer(&tt->actions);
    tt->tables = newHTable(16);
    tt->tables->free_symbol = tt_free_table_symbol;
    LD->transaction.table_trail = tt;
  }

  return tt;
}


static void
tbl_trail_free(tbl_trail *tt)
{ discardBuffer(&tt->actions);
  destroyHTable(tt->tables);
  freeHeap(tt, sizeof(*tt));
}


#define tt_alloc(bytes) LDFUNC(tt_alloc, bytes)
static void *
tt_alloc(DECL_LD size_t bytes)
{ tbl_trail *tt = tt_trail();
  size_t *szp;
  char *buf;

  buf  = allocFromBuffer(&tt->actions, bytes+sizeof(*szp));
  szp  = (size_t*)&buf[bytes];
  *szp = bytes;

  return buf;
}


static void
tt_add_table(DECL_LD trie *atrie, int flags)
{ if ( LD->transaction.generation )
  { tbl_trail *tt = tt_trail();
    atom_t symbol = trie_symbol(atrie);

    updateHTable(tt->tables, (table_key_t)symbol, (table_value_t)flags);
    PL_register_atom(symbol);
  }
}


/* - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - -
A    monotonic    new    answer    was      added    to    atrie    from
`$tbl_monotonic_add_answer`/2. If the table is not marked to be (forced)
reevaluated already, we record the answer in our trail.
- - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - */

#define tt_add_answer(atrie, node) LDFUNC(tt_add_answer, atrie, node)
static void
tt_add_answer(DECL_LD trie *atrie, trie_node *node)
{ if ( LD->transaction.generation )
  { idg_node *idg;

    if ( !((idg=atrie->data.IDG) && idg->tt_notrail) )
    { tbl_trail *tt = tt_trail();

      if ( !lookupHTable(tt->tables, (table_key_t)trie_symbol(atrie)) )
      { tbl_trail_answer *a = tt_alloc(sizeof(*a));
	a->type   = TT_ANSWER;
	a->atrie  = atrie;
	a->answer = node;

	if ( isoff(atrie, TRIE_ISTRACKED) )
	  set(atrie, TRIE_ISTRACKED);
      }
    }
  }
}


/* - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - -
tt_abolish_table(trie *atrie) is called  when   atrie  is  abolished. It
discards all answers that have been registered with this table.
- - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - */

static void
tt_abolish_table(trie *atrie)
{ GET_LD
  tbl_trail *tt;

  if ( (tt=LD->transaction.table_trail) )
  { size_t *base = baseBuffer(&tt->actions, size_t);
    size_t *top  = topBuffer(&tt->actions, size_t);

    while(top>base)
    { tbl_trail_any *tsz;
      size_t bytes = *--top;

      top = addPointer(top, -bytes);
      tsz = (tbl_trail_any*)top;

      switch(tsz->type)
      { case TT_ANSWER:
	{ tbl_trail_answer *ta = (tbl_trail_answer*)tsz;

	  if ( ta->atrie == atrie )
	  { ta->atrie = NULL;
	    ta->answer = NULL;
	  }

	  break;
	}
	default:
	  assert(0);
      }
    }
  }
}


int
transaction_commit_tables(DECL_LD)
{ tbl_trail *tt;

  if ( (tt=LD->transaction.table_trail) )
  { size_t *base = baseBuffer(&tt->actions, size_t);
    size_t *top  = topBuffer(&tt->actions, size_t);

    LD->transaction.table_trail = NULL;

    while(top>base)
    { tbl_trail_any *tsz;
      size_t bytes = *--top;

      top = addPointer(top, -bytes);
      tsz = (tbl_trail_any*)top;

      switch(tsz->type)
      { case TT_ANSWER:
	  break;
	default:
	  assert(0);
      }
    }

    tbl_trail_free(tt);
  }

  return true;
}


/* - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - -
Rollback a new monotonic anwser. If the   table is eager this is simple:
just remove the answer. If it is lazy, the answer may be propagated into
the queues of affected tables, so we need to prune these.
- - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - */

static void
tt_rollback_answer(trie *atrie, trie_node *answer)
{ idg_node *idg;

  DEBUG(MSG_TABLING_TRANSACTION,
	print_answer("Rollback: ", answer));

  if ( (idg=atrie->data.IDG) && idg->lazy )
  { word v = answer->value;

    answer->value = 0;
    prune_deleted_mdeps(idg);
    answer->value = v;
  }

  trie_delete(atrie, answer, true);
}


static int
tt_rollback_tables(Table affected)
{ int rc = true;

  FOR_TABLE(affected, n, v)
  { atom_t symbol = (atom_t)n;
    int flags = (int)(uintptr_t) v;
    trie *atrie = symbol_trie(symbol);
    idg_node *n;

    DEBUG(0,assert(flags==TT_TBL_INVALIDATE));
    (void)flags;

    if ( (n=atrie->data.IDG) )
    { int flags = IDG_CHANGED_NODE;

      if ( n->monotonic )
	flags |= IDG_CHANGED_MONO;

      if ( !idg_changed(atrie, flags) )
	rc = false;		/* can this happen? */
      if ( n->monotonic && !n->force_reeval )
	n->force_reeval = true;
    }
  }

  return rc;
}


static int
tt_rollback_actions(Buffer b)
{ size_t *base = baseBuffer(b, size_t);
  size_t *top  = topBuffer(b, size_t);

  while( top > base )
  { tbl_trail_any *tsz;
    size_t bytes = *--top;

    top = addPointer(top, -bytes);
    tsz = (tbl_trail_any*)top;

    switch(tsz->type)
    { case TT_ANSWER:
      { tbl_trail_answer *ta = (tbl_trail_answer*)tsz;

	if ( ta->atrie )
	  tt_rollback_answer(ta->atrie, ta->answer);
	break;
      }
      default:
	assert(0);
    }
  }

  return true;
}


int
transaction_rollback_tables(DECL_LD)
{ tbl_trail *tt;
  int rc = true;

  if ( (tt=LD->transaction.table_trail) )
  { LD->transaction.table_trail = NULL;

    rc = tt_rollback_tables(tt->tables);
    rc = tt_rollback_actions(&tt->actions) && rc;

    tbl_trail_free(tt);
  }

  return rc;
}

void
merge_tabling_trail(tbl_trail *into, tbl_trail *from)
{ size_t bytes = sizeOfBuffer(&from->actions);
  void *to = allocFromBuffer(&into->actions, bytes);

  memcpy(to, baseBuffer(&from->actions, char), bytes);
  discardBuffer(&from->actions);
  freeHeap(from, sizeof(*from));
}


		 /*******************************
		 *	 IDG CONSTRUCTION	*
		 *******************************/

static idg_node *
idg_new(trie *atrie)
{ idg_node *n = PL_malloc(sizeof(*n));

  memset(n, 0, sizeof(*n));
  n->magic = IDG_NODE_MAGIC;
  n->atrie = atrie;

  return n;
}

static void
idg_clean_affected(idg_node *node)
{ TablePP table;

  if ( (table=node->affected) )
    clearHTablePP(table);
}

static void
idg_clean_dependent(idg_node *node)
{ TablePP table;

  if ( (table=node->dependent) )
    clearHTablePP(table);
}


static void
idg_reset(idg_node *node)
{ idg_clean_affected(node);
  idg_clean_dependent(node);
  node->answer_count = 0;
  node->new_answer   = false;
  node->reevaluating = false;
  node->falsecount   = 0;
}

static void
idg_destroy(idg_node *node)
{ TablePP table;

  if ( (table=node->affected) )
  { node->affected = NULL;
    destroyHTablePP(table);
  }
  if ( (table=node->dependent) )
  { node->dependent = NULL;
    destroyHTablePP(table);
  }

  PL_free(node);
}

static idg_node *
free_mdep_chain(idg_node *child)
{ while ( child->magic != IDG_NODE_MAGIC )
  { idg_mdep *mdep = (idg_mdep*)child;

    child = mdep->next.child;
    free_mdep(mdep);
  }

  return child;
}

static void
idg_free_affected(table_key_t n, table_value_t v)
{ idg_node *child  = val2ptr(v);
  idg_node *parent = key2ptr(n);

  child = free_mdep_chain(child);

  assert(parent->dependent);
  if ( !deleteHTablePP(parent->dependent, child) )
    Sdprintf("OOPS: idg_free_affected() failed to delete backlink\n");
}

static void
idg_free_dependent(table_key_t n, table_value_t v)
{ idg_node *parent = val2ptr(v);
  idg_node *child  = key2ptr(n);

  assert(child->affected);
  if ( (child=deleteHTablePP(child->affected, parent)) )
    free_mdep_chain(child);
  else
    Sdprintf("OOPS: idg_free_dependent() failed to delete backlink\n");
}


/**
 * Throw error(dependency_error(shared(Parent), private(Child)), _)
 */

#define idg_dependency_error(parent, child) LDFUNC(idg_dependency_error, parent, child)
static int
idg_dependency_error(DECL_LD idg_node *parent, idg_node *child)
{ term_t av;

  return ( (av=PL_new_term_refs(3)) &&
	   unify_trie_term(parent->atrie->data.variant, NULL, av+0) &&
	   unify_trie_term(child->atrie->data.variant,  NULL, av+1) &&
	   PL_unify_term(av+2,
			 PL_FUNCTOR, FUNCTOR_error2,
			   PL_FUNCTOR_CHARS, "dependency_error", 2,
			     PL_FUNCTOR_CHARS, "shared", 1, PL_TERM, av+0,
			     PL_FUNCTOR_CHARS, "private", 1,PL_TERM, av+1,
			   PL_VARIABLE) &&
	   PL_raise_exception(av+2));
}


#define idg_dependency_error_dyncall(parent, call) LDFUNC(idg_dependency_error_dyncall, parent, call)
static int
idg_dependency_error_dyncall(DECL_LD idg_node *parent, term_t call)
{ term_t av;

  return ( (av=PL_new_term_refs(2)) &&
	   unify_trie_term(parent->atrie->data.variant, NULL, av+0) &&
	   PL_unify_term(av+1,
			 PL_FUNCTOR, FUNCTOR_error2,
			   PL_FUNCTOR_CHARS, "idg_dependency_error", 2,
			     PL_FUNCTOR_CHARS, "shared", PL_TERM, av+0,
			     PL_FUNCTOR_CHARS, "private", PL_TERM, call,
			   PL_VARIABLE) &&
	   PL_raise_exception(av+1));
}


#define idg_dependency_error_mono(src_trie, dst_trie) LDFUNC(idg_dependency_error_mono, src_trie, dst_trie)
static int
idg_dependency_error_mono(DECL_LD trie *src_trie, trie *dst_trie)
{ term_t av;

  return ( (av=PL_new_term_refs(3)) &&
	   unify_trie_term(dst_trie->data.variant, NULL, av+0) &&
	   unify_trie_term(src_trie->data.variant,  NULL, av+1) &&
	   PL_unify_term(av+2,
			 PL_FUNCTOR, FUNCTOR_error2,
			   PL_FUNCTOR_CHARS, "dependency_error", 2,
			     PL_TERM, av+0,
			     PL_FUNCTOR_CHARS, "monotonic", 1,PL_TERM, av+1,
			   PL_VARIABLE) &&
	   PL_raise_exception(av+2));
}

/* - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - -
Create a bi-directional link between parent and   child node. We use the
hash tables as sets only, but we use   the _other side_ as entry _value_
to recover the full link and allow   ->free_symbol()  to delete the back
pointer.

For monotonic tabling we need to store   the continuation along with the
edge. This is passed as  a  Prolog   term  in  the `dep` parameter. This
causes the link from the child to   the parent (child->affected) to be a
pointer to an `mdep` structure. See new_mdep().
- - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - */

#define idg_add_child(parent, child, dep, flags) LDFUNC(idg_add_child, parent, child, dep, flags)
static int
idg_add_child(DECL_LD idg_node *parent, idg_node *child, term_t dep, int flags)
{ volatile TablePP t;

  DEBUG(MSG_TABLING_IDG,
	{ term_t f = PL_new_term_ref();
	  term_t t = PL_new_term_ref();
	  unify_trie_term( child->atrie->data.variant, NULL, f);
	  unify_trie_term(parent->atrie->data.variant, NULL, t);
	  Sdprintf("IDG: Edge %s", dep ? "(dep) " : "");
	  PL_write_term(Serror, f, 999, 0);
	  Sdprintf(" [fc=%d] -> ", child->falsecount);
	  PL_write_term(Serror, t, 999, 0);
	  Sdprintf(" [fc=%d]\n", parent->falsecount);
	});

  if ( ison(parent->atrie, TRIE_ISSHARED) &&
       isoff(child->atrie, TRIE_ISSHARED) )
    return idg_dependency_error(parent, child);

  if ( !(t=child->affected) )
  { t = newHTablePP(4);
    t->free_symbol = idg_free_affected;
    if ( !COMPARE_AND_SWAP_PTR(&child->affected, NULL, t) )
    { destroyHTablePP(t);
      t = child->affected;
    }
  }
  if ( dep )
  { idg_mdep *mdep0 = addHTablePP(t, parent, child); /* chain old dependency */
    idg_mdep *mdep;

    switch( find_dep(mdep0, dep, &mdep) )
    { case true:
	break;
      case false:
	DEBUG(MSG_TABLING_IDG,
	      Sdprintf("  New dependency\n"));
	if ( !(mdep=new_mdep(dep)) )
	  return false;
	if ( child->lazy )
	  parent->lazy = true;
	if ( parent->lazy )
	  mdep->lazy = true;
	mdep->next.any = mdep0;
	updateHTablePP(t, parent, mdep);
	break;
      default:
	return false;				   /* resource error */
    }

    if ( mdep->lazy && LD->transaction.generation &&
	 child->atrie->data.worklist == WL_DYNAMIC &&
	 LD->transaction.predicates &&
	 lookupHTablePW(LD->transaction.predicates,
			child->atrie->data.predicate) )
      parent->tt_new_dep = true;
  } else
  { addHTablePP(t, parent, child);
  }

  if ( !(t=parent->dependent) )
  { t = newHTablePP(4);
    t->free_symbol = idg_free_dependent;
    if ( !COMPARE_AND_SWAP_PTR(&parent->dependent, NULL, t) )
    { destroyHTablePP(t);
      t = parent->dependent;
    }
  }
  addHTablePP(t, child, parent);

  return true;
}


static int
idg_init_variant(DECL_LD trie *atrie, Definition def, term_t variant)
{ if ( !atrie->data.IDG )
  { if ( unlikely(!def) )
    { Procedure proc;

      if ( get_procedure(variant, &proc, 0, GP_RESOLVE|GP_EXISTENCE_ERROR) )
	def = proc->definition;
      else
	return false;
    }

    if ( (def->tabling && ison(def->tabling, TP_MONOTONIC|TP_INCREMENTAL)) )
    { idg_node *n = idg_new(atrie);

      if ( def->tabling )
      { if ( ison(def->tabling, TP_MONOTONIC) )
	  n->monotonic = true;
	if ( ison(def->tabling, TP_LAZY) )
	  n->lazy = true;
      }

      if ( !COMPARE_AND_SWAP_PTR(&atrie->data.IDG, NULL, n) )
	idg_destroy(n);
    }
  }

  return true;
}


#define set_idg_current(atrie) LDFUNC(set_idg_current, atrie)
static int
set_idg_current(DECL_LD trie *atrie)
{ int rc;
  Word p;

  if ( (rc=ensureGlobalSpace(0, ALLOW_GC)) != true )
    return raiseStackOverflow(rc);
  p = valTermRef(LD->tabling.idg_current);
  TrailAssignment(p);
  if ( atrie )
    *p = trie_symbol(atrie);
  else
    setVar(*p);

  return true;
}

#define idg_current(_) LDFUNC(idg_current, _)
static trie *
idg_current(DECL_LD)
{ word current = *valTermRef(LD->tabling.idg_current);

  if ( current )
  { DEBUG(0, assert(isAtom(current)));
    return symbol_trie(word2atom(current));
  }

  return NULL;
}



/** Add an edge from the current node to the new child represented
 * by `atrie`.  If `ctrie` is given it is used.  Otherwise idg_current()
 * is used.
 *
 *   - true:  created a dependency
 *   - false: something is wrong
 *   - -1:    there is no current node
 */

static int
idg_add_edge(DECL_LD trie *atrie, trie *ctrie)
{ if ( atrie->data.IDG )
  { if ( !ctrie )
      ctrie = idg_current();

    if ( ctrie && ctrie->data.IDG )
      return idg_add_child(ctrie->data.IDG, atrie->data.IDG, 0, 0);
  }

  return -1;
}

/** '$idg_add_edge'(+ATrie) is det.
 *
 * Add a child to the current dependency tree.  Used by tnot/1
 * if the tnot is resolved from an already existing table.
 */

static
PRED_IMPL("$idg_add_edge", 1, idg_add_edge, 0)
{ PRED_LD
  trie *ctrie = idg_current();

  if ( ctrie && ctrie->data.IDG )
  { trie *atrie;

    if ( get_trie(A1, &atrie) )
      return !!idg_add_edge(atrie, ctrie);

    return false;
  }

  return true;
}


/** '$idg_set_current'(-OldCurrent, +ATrie)
 *
 * Set the current to Atrie and return the old current.
 */

static
PRED_IMPL("$idg_set_current", 2, idg_set_current, 0)
{ PRED_LD
  trie *atrie;

  if ( get_trie(A2, &atrie) )
  { atom_t current;

    if ( (current = word2atom(*valTermRef(LD->tabling.idg_current))) )
    { if ( !PL_unify_atom(A1, current) )
	return false;
    }
    return set_idg_current(atrie);
  }

  return false;
}


/** '$idg_add_dyncall'(+Variant)
 *
 * Called on a call to an incremental dynamic predicate.
 *
 * (*) If we make a call we should reset the `falsecount` to 0 as this
 * may have added a new dependency.  Ideally we should keep track of the
 * edges we have signalled, although we need to lookup the dynamic trie
 * from the assert/removed variant anyway and propagation to node that
 * have already been triggered stop quickly.  Setting the `falsecount`
 * to zero should be considered similar to re-evaluating an incremental
 * tabled predicate when it is called.
 */

#define trie_for_dynamic_predicate(def, ctrie, variant) LDFUNC(trie_for_dynamic_predicate, def, ctrie, variant)
static trie *
trie_for_dynamic_predicate(DECL_LD Definition def, trie *ctrie, term_t variant)
{ trie *atrie;
  int flags = (AT_CREATE|AT_NOCLAIM);

  if ( ison(ctrie, TRIE_ISSHARED) )
  { flags |= AT_SHARED;

    /* a shared table cannot depend on a thread-local predicate */
    /* TBD: Avoid the procedure lookup! */
    if ( !def )
    { Procedure proc;

      if ( get_procedure(variant, &proc, 0, GP_RESOLVE) &&
	   ison(proc->definition, P_THREAD_LOCAL) )
      { return idg_dependency_error_dyncall(ctrie->data.IDG,
					    variant),NULL;
      }
    } else if ( ison(def, P_THREAD_LOCAL) )
    { return idg_dependency_error_dyncall(ctrie->data.IDG, variant),NULL;
    }
  } else
  { flags |= AT_PRIVATE;
  }

  if ( (atrie=get_answer_table(NULL, variant, 0, NULL, flags)) )
  { if ( !atrie->data.IDG )
    { idg_node *n;

      assert(!atrie->data.worklist || atrie->data.worklist == WL_GROUND);
      atrie->data.worklist = WL_DYNAMIC;
      atrie->data.predicate = def;
      n = idg_new(atrie);
      if ( !COMPARE_AND_SWAP_PTR(&atrie->data.IDG, NULL, n) )
	idg_destroy(n);
    }

    atrie->data.IDG->falsecount = 0;	/* see (*) above */

    return atrie;
  }

  return NULL;
}


int
idg_add_dyncall(DECL_LD Definition def, trie *ctrie, term_t variant)
{ trie *atrie;

  if ( (atrie=trie_for_dynamic_predicate(def, ctrie, variant)) )
  { idg_add_edge(atrie, ctrie);
    return true;
  }

  return false;
}


static
PRED_IMPL("$idg_add_dyncall", 1, idg_add_dyncall, 0)
{ PRED_LD
  trie *ctrie = idg_current();

  if ( ctrie && ctrie->data.IDG )
    return idg_add_dyncall(NULL, ctrie, A1);

  return true;
}


static int
idg_set_current_wl(DECL_LD term_t wlref)
{ worklist *wl;

  if ( get_worklist(wlref, &wl) )
  { trie *atrie = wl->table;

    DEBUG(MSG_TABLING_IDG,
	  { term_t t = PL_new_term_ref();
	    unify_trie_term(atrie->data.variant, NULL, t);
	    Sdprintf("IDG: Set current to ");
	    PL_write_term(Serror, t, 999, PL_WRT_NEWLINE);
	  });

    return set_idg_current(atrie);
  }

  return false;
}

static
PRED_IMPL("$idg_set_current", 1, idg_set_current, 0)
{ PRED_LD
  trie *atrie;

  if ( get_trie_noex(A1, &atrie) )
  { DEBUG(MSG_TABLING_IDG,
	  { term_t t = PL_new_term_ref();
	    unify_trie_term(atrie->data.variant, NULL, t);
	    Sdprintf("IDG: Set current to ");
	    PL_write_term(Serror, t, 999, PL_WRT_NEWLINE);
	  });

    return set_idg_current(atrie);
  } else
  { return set_idg_current(NULL);
  }

  return true;
}


static
PRED_IMPL("$idg_reset_current", 0, idg_reset_current, 0)
{ PRED_LD

  return set_idg_current(NULL);
}


		 /*******************************
		 *	    IDG QUERYING	*
		 *******************************/

typedef struct idg_edge_state
{ trie *	atrie;
  TablePP	table;
  TableEnum	tenum;
  atom_t	dir;
  int		fixed_dir;
  int		allocated;
  int		monotonic;
  int		lazy;
  int		force_reeval;
  int		dyn_or_complete;
  atom_t	deptrie_symbol;
  idg_mdep     *dependencies;
} idg_edge_state;


static int
advance_idg_edge_state(idg_edge_state *state)
{
retry:
  if ( state->monotonic &&
       state->dependencies &&
       state->dependencies->next.any &&
       state->dependencies->next.dep->magic == IDG_MDEP_MAGIC )
  { state->dependencies = state->dependencies->next.dep;
    return true;
  }

  table_key_t k;
  table_value_t v;
  if ( advanceTableEnum(state->tenum, &k, &v) )
  { idg_node *n = key2ptr(k);
    idg_mdep *mdep;

    if ( state->lazy )			/* Lazy requires reverse lookup */
    { GET_LD
      mdep = lookupHTablePP(n->affected, state->atrie->data.IDG);
    } else
    { mdep = val2ptr(v);
    }

    state->dependencies = NULL;
    if ( mdep->magic == IDG_MDEP_MAGIC )
    { state->dependencies = mdep;
      state->force_reeval = n->force_reeval;
    }

    state->deptrie_symbol = trie_symbol(n->atrie);
    return true;
  } else
  { freeTableEnum(state->tenum);
    state->tenum = NULL;

    if ( !state->fixed_dir && state->dir == ATOM_affected )
    { if ( (state->table = state->atrie->data.IDG->dependent) )
      { state->dir = ATOM_dependent;
	state->tenum = newTableEnumPP(state->table);
	goto retry;
      }
    }
  }

  return false;
}

static void
free_idg_edge_state(idg_edge_state *state)
{ if ( state->tenum )
    freeTableEnum(state->tenum);
  if ( state->allocated )
    freeForeignState(state, sizeof(*state));
}

static idg_edge_state *
save_idg_edge_state(idg_edge_state *state)
{ if ( !state->allocated )
  { idg_edge_state *n = allocForeignState(sizeof(*n));

    *n = *state;
    n->allocated = true;
    return n;
  }

  return state;
}

#define IDG_MONO_AFFECTS 0x1


static foreign_t
idg_edge_gen(term_t from, term_t dir, term_t To, term_t dep, term_t depref,
	     term_t answers, term_t status, int flags, control_t PL__ctx)
{ PRED_LD
  idg_edge_state sbuf;
  idg_edge_state *state;

  switch( CTX_CNTRL )
  { case FRG_FIRST_CALL:
    { trie *to;

      state = &sbuf;
      memset(state, 0, sizeof(*state));

      if ( !get_trie(from, &state->atrie) )
	return false;
      if ( !state->atrie->data.IDG )
	return false;

      if ( !dir )
      { state->fixed_dir = true;
	if ( status )			/* '$idg_false_edge'/3 */
	{ state->lazy    = false;
	  state->dir     = ATOM_dependent;
	  state->table   = state->atrie->data.IDG->dependent;
	} else
	{ state->monotonic = true;
	  if ( answers )		/* '$idg_mono_affects_lazy'/5 */
	  { if ( !state->atrie->data.IDG->lazy )
	      return false;
	    state->lazy    = true;
	    state->dir     = ATOM_dependent;
	    state->table   = state->atrie->data.IDG->dependent;
	  } else			/* '$idg_mono_affects[_eager]'/3 */
	  { state->lazy    = false;
	    state->dir     = ATOM_affected;
	    state->table   = state->atrie->data.IDG->affected;
	  }
	}
      } else if ( PL_is_variable(dir) )
      { if ( (state->table = state->atrie->data.IDG->affected) )
	{ state->dir = ATOM_affected;
	} else if ( (state->table = state->atrie->data.IDG->dependent) )
	{ state->dir = ATOM_dependent;
	  if ( !PL_unify_atom(dir, ATOM_dependent) )
	    return false;
	  state->fixed_dir = true;
	} else
	  return false;
      } else if ( PL_get_atom_ex(dir, &state->dir) )
      { state->fixed_dir = true;
	if ( state->dir == ATOM_affected )
	  state->table = state->atrie->data.IDG->affected;
	else if ( state->dir == ATOM_dependent )
	  state->table = state->atrie->data.IDG->dependent;
	else
	  return PL_domain_error("idg_edge_dir", dir);
      }

      if ( !state->table )
	return false;

      if ( PL_is_variable(To) )
      { state->tenum = newTableEnumPP(state->table);
	if ( advance_idg_edge_state(state) )
	  break;
	free_idg_edge_state(state);
	return false;
      } else if ( get_trie(To, &to) )
      { return !!lookupHTablePP(state->table, to->data.IDG);
      }
    }
    case FRG_REDO:
      state = CTX_PTR;
      break;
    case FRG_CUTTED:
      state = CTX_PTR;
      free_idg_edge_state(state);
      return true;
    default:
      assert(0);
      return false;
  }

  Mark(fli_context->mark);
  do
  { if ( dep )				/* monotonic dependency */
    { idg_mdep *mdep;

      if ( (mdep=state->dependencies) &&
	   (state->lazy == mdep->lazy || (flags & IDG_MONO_AFFECTS)) &&
	   !state->force_reeval )
      { term_t t;

	if ( answers )
	{ int rc;

	  if ( !(flags & IDG_MONO_AFFECTS) &&
	       !(mdep->queue && !isEmptyBuffer(mdep->queue)) )
	    goto next;			/* no answers on this dependency */

	  if ( (rc=mdep_unify_answers(answers, mdep)) == -1 )
	    goto out_error;
	  if ( rc == 0 )
	    goto next;			/* no real answers */

	  if ( !PL_unify_pointer(depref, mdep) )
	    goto out_error;

	}

	if ( !(t = PL_new_term_ref()) ||
	     !put_fastheap(mdep->dependency, t) ||
	     !PL_unify(t, dep) )
	  return false;
      } else
      { goto next;
      }
    }

    if ( status )			/* '$idg_false_edge'/3 */
    { trie *dtrie = symbol_trie(state->deptrie_symbol);
      atom_t astat;

      if ( (astat=table_status_reeval_wait(dtrie)) )
      { if ( astat == ATOM_dynamic || astat == ATOM_complete )
	{ if ( state->dyn_or_complete )
	    goto next;
	  else
	    state->dyn_or_complete = true;
	}

	if ( !PL_unify_atom(status, astat) )
	  goto out_error;
      } else
      { goto out_error;			/* Deadlock */
      }
    }

    if ( PL_unify_atom(To, state->deptrie_symbol) )
    { if ( state->fixed_dir ||
	   PL_unify_atom(dir, state->dir) )
      { if ( advance_idg_edge_state(state) )
	  ForeignRedoPtr(save_idg_edge_state(state));
	free_idg_edge_state(state);
	return true;
      }
    }

    if ( PL_exception(0) )
      goto out_error;

  next:
    Undo(fli_context->mark);
  } while(advance_idg_edge_state(state));

out_fail:
  free_idg_edge_state(state);
  return false;

out_error:
  assert(PL_exception(0));
  goto out_fail;
}


/** '$idg_edge'(+ATrie, ?Direction, -DTrie)
 *
 * Enumerate over the edges of the dependency graph.
 */

static
PRED_IMPL("$idg_edge", 3, idg_edge, PL_FA_NONDETERMINISTIC)
{ return idg_edge_gen(A1, A2, A3, 0, 0, 0, 0, 0, PL__ctx);
}

/** '$idg_false_edge'(+ATrie, -DTrie, -Status)
 *
 *  Similar to '$idg_edge'(ATrie, dependent, DTrie), but only generates
 *  one solution for dynamic and complete edges. Also produces the
 *  status for DTrie as '$tbl_reeval_wait'/2.
 */

static
PRED_IMPL("$idg_false_edge", 3, idg_false_edge, PL_FA_NONDETERMINISTIC)
{ return idg_edge_gen(A1, 0, A2, 0, 0, 0, A3, 0, PL__ctx);
}

/** '$idg_mono_affects_eager'(+SrcTrie, -DstTrie, -Dependency)
 */

static
PRED_IMPL("$idg_mono_affects_eager", 3, idg_mono_affects_eager,
	  PL_FA_NONDETERMINISTIC)
{ return idg_edge_gen(A1, 0, A2, A3, 0, 0, 0, IDG_MONO_AFFECTS, PL__ctx);
}

/** '$idg_mono_affects'(+SrcTrie, -DstTrie, -Dependency)
 */

static
PRED_IMPL("$idg_mono_affects", 3, idg_mono_affects,
	  PL_FA_NONDETERMINISTIC)
{ return idg_edge_gen(A1, 0, A2, A3, 0, 0, 0, IDG_MONO_AFFECTS, PL__ctx);
}

/** '$idg_mono_affects_lazy'(+DstTrie, -SrcTrie, -Dependency, -Answers)
 *
 * True when Answer needs to be propagated through Dependency to update
 * DstTrie.
 */

static
PRED_IMPL("$idg_mono_affects_lazy", 5, idg_mono_affects_lazy,
	  PL_FA_NONDETERMINISTIC)
{ return idg_edge_gen(A1, 0, A2, A3, A4, A5, 0, 0, PL__ctx);
}


/** '$tbl_node_answer'(+NodeRef, -Answer) is det.
 *
 *  Get the answer associated with a node.  If the answer is moded,
 *  return as Primary/Moded
*/

static
PRED_IMPL("$tbl_node_answer", 2, tbl_node_answer, 0)
{ PRED_LD
  void *ptr;

  return ( PL_get_pointer_ex(A1, &ptr) &&
	   tbl_unify_answer(ptr, A2)
	 );
}


/* - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - -
(*) If not-changed propagation re-validates  the   table  someone may be
waiting for it and we must release   ownership  for the table and signal
possible waiters.

It is probably possible we re-validate a   table that is claimed by some
other thread. What should we do in this case?

(**) If we  have  a  normal   incremental  change  (retract  or modified
dependent table) we have to give  up   on  lazy monotonic evaluation for
affected nodes. This means we clean  the monotonic dependency queues and
set `force_reeval` to  make  reeval_node/1   do  the  normal incremental
reevaluation.

(***) We can decrement below zero   if an internal '$mono_reeval_done'/3
completes a component after  which  a   more  external  one propagates a
no-change. Giving up this sanity check is dubious. Possibly we need some
other way to detect this situation.
- - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - */

typedef struct idg_propagate_state
{ size_t modified;
  trie *incomplete;				/* hit an incomplete trie */
  TableEnum en;
  segstack  stack;
  idg_node  *buf[100];
} idg_propagate_state;

#ifdef O_DEBUG
static const char *
idg_flag_name(int flags)
{ static char buf[100];
  char *s = buf;

  *s = 0;
  if ( flags&IDG_CHANGED_NODE )
  { strcpy(s, "NODE"); s+= strlen(s);
  }
  if ( flags&IDG_CHANGED_MONO )
  { if ( s > buf ) *s++ = '|';
    strcpy(s, "MONO"); s+= strlen(s);
  }
  if ( flags&IDG_PROPAGATE_FORCE )
  { if ( s > buf ) *s++ = '|';
    strcpy(s, "FORCE"); s+= strlen(s);
  }

  return buf;
}
#endif

#define idg_changed_loop(state, flags) LDFUNC(idg_changed_loop, state, flags)
static void
idg_changed_loop(DECL_LD idg_propagate_state *state, int flags)
{ typedef struct idg_node *IDGNode;

  for(;;)
  { table_key_t k;
    table_value_t v;
    idg_node *next;

    while( advanceTableEnum(state->en, &k, &v) )
    { idg_node *n = key2ptr(k);

      DEBUG(MSG_TABLING_IDG_CHANGED,
	    print_answer_table(
		n->atrie,
		"  IDG: propagate falsecount (%s re-eval=%d, falsecount=%d)",
		(flags&IDG_PROPAGATE_FORCE) ? "->incr" :
		   (flags&IDG_CHANGED_NODE) ? "+1" : "-1",
		n->reevaluating, n->falsecount));

      if ( n->reevaluating )
	continue;

      if ( (flags&IDG_PROPAGATE_FORCE) )	/* See (**) */
      { DEBUG(MSG_TABLING_MONOTONIC,
	      print_answer_table(
		  n->atrie,
		  "  Monotonic to incremental evaluation (I)"));

	if ( n->monotonic && !n->force_reeval )
	{ mdep_empty_queues(val2ptr(v));
	  force_reeval(n);
	}
	continue;
      }

      if ( (flags&IDG_CHANGED_NODE) )		/* Increment falsecount */
      { if ( table_is_incomplete(n->atrie) )
	  state->incomplete = n->atrie;		/* return? */

	if ( n->monotonic && !n->force_reeval && !(flags&IDG_CHANGED_MONO) )
	{ DEBUG(MSG_TABLING_MONOTONIC,
	      print_answer_table(
		  n->atrie,
		  "  Monotonic to incremental evaluation (II)"));

	  mdep_empty_queues(val2ptr(v));
	  force_reeval(n);
	  idg_propagate_change(n, IDG_PROPAGATE_FORCE);
	}

	if ( ATOMIC_INC(&n->falsecount) == 1 )
	{ TRIE_STAT_INC(n, invalidated);
	  if ( n->affected )
	  { if ( !pushSegStack(&state->stack, n, IDGNode) )
	      outOfCore();
	  }
	}
      } else if ( !table_is_incomplete(n->atrie) &&
		  !n->mono_reevaluating &&
		  (n->monotonic ? n->falsecount > 0 : true /* see (***) */) )
      { int fc = ATOMIC_DEC(&n->falsecount);	/* Decrement falsecount */

	assert(fc >= 0);
	if ( fc == 0 )
	{ n->force_reeval = false;

#ifdef O_PLMT
	  if ( ison(n->atrie, TRIE_ISSHARED) && n->atrie->tid )
	  { if ( n->atrie->tid == PL_thread_self() ) /* See (*) */
	      COMPLETE_WORKLIST(n->atrie, (void)0);
	    else
	      Sdprintf("IDG falsecount propagation re-validated a table "
		       "from another thread\n");
	  }
#endif
	  if ( n->affected )
	  { if ( !pushSegStack(&state->stack, n, IDGNode) )
	      outOfCore();
	  }
	}
      }
    }
    freeTableEnum(state->en);

    if ( popSegStack(&state->stack, &next, IDGNode) )
    { assert(next->affected);
      state->en = newTableEnumPP(next->affected);
    } else
      break;
  }
}


static trie *
idg_propagate_change(idg_node *n, int flags)
{ if ( n->affected )
  { GET_LD
    idg_propagate_state state;

    DEBUG(MSG_TABLING_IDG_CHANGED,
	  print_answer_table(n->atrie, "IDG propagate change (flags=%s)",
			     idg_flag_name(flags)));

    state.modified = 0;
    state.incomplete = NULL;
    initSegStack(&state.stack, sizeof(idg_node*), sizeof(state.buf), state.buf);
    state.en = newTableEnumPP(n->affected);
    idg_changed_loop(&state, flags);
    clearSegStack(&state.stack);

    return state.incomplete;
  }

  return NULL;
}


static int
change_incomplete_error(trie *atrie)
{ GET_LD
  term_t v;

  return ( (v=PL_new_term_ref()) &&
	   unify_trie_term(atrie->data.variant, NULL, v) &&
	   PL_permission_error("update", "variant", v) );
}


static int
idg_need_invalidated(idg_node *n)
{ TablePP t;

  if ( n->atrie->data.worklist == WL_DYNAMIC ||
       (n->monotonic && !n->lazy) )
    return (t=n->affected) && t->size > 0;

  return true;
}


static int
idg_changed(trie *atrie, int flags)
{ idg_node *n;

  DEBUG(MSG_TABLING_IDG_CHANGED,
	print_answer_table(atrie, "IDG: %s change",
			   flags&IDG_CHANGED_MONO ? "lazy monotonic"
						  : "dynamic"));

  if ( (n=atrie->data.IDG) && n->falsecount == 0 && idg_need_invalidated(n) )
  { trie *incomplete;

    DEBUG(MSG_TABLING_IDG_CHANGED, Sdprintf(" (propagating)\n"));

    if ( table_is_incomplete(atrie) )
    { if ( flags&IDG_CHANGED_MONO )
      { DEBUG(MSG_TABLING_IDG_CHANGED,
	      Sdprintf("Incomplete table: stopping propagation\n"));
	return true;
      }
      return change_incomplete_error(atrie);
    }
    if ( ATOMIC_INC(&n->falsecount) == 1 )
    { TRIE_STAT_INC(n, invalidated);
      if ( (incomplete=idg_propagate_change(n, flags)) )
      { n->falsecount = 0;
	idg_propagate_change(n, 0);
	return change_incomplete_error(incomplete);
      }
    }
  } else
  { DEBUG(MSG_TABLING_IDG_CHANGED,
	  if ( n ) Sdprintf(" (already changed (%d))\n", n->falsecount);
	  else Sdprintf(" (no IDG)\n"));
  }

  return true;
}


static
PRED_IMPL("$idg_changed", 1, idg_changed, 0)
{ trie *atrie;

  if ( get_trie(A1, &atrie) )
    return idg_changed(atrie, IDG_CHANGED_NODE);

  return false;
}


static
PRED_IMPL("$idg_falsecount", 2, idg_falsecount, 0)
{ PRED_LD
  trie *atrie;

  if ( get_trie(A1, &atrie) )
  { idg_node *n;

    if ( (n=atrie->data.IDG) )
      return PL_unify_integer(A2, n->falsecount);

    return false;
  }

  return false;
}


static
PRED_IMPL("$idg_set_falsecount", 2, idg_set_falsecount, 0)
{ trie *atrie;

  if ( get_trie(A1, &atrie) )
  { idg_node *n;

    if ( (n=atrie->data.IDG) )
      return PL_get_integer_ex(A2, &n->falsecount);

    return false;
  }

  return false;
}


		 /*******************************
		 *     MONOTONIC TABLING	*
		 *******************************/

static void dep_free_queue(Buffer queue);

#define mdep_hash(dep)		   LDFUNC(mdep_hash, dep)

static unsigned int
mdep_hash(DECL_LD term_t dep)
{ termhash_t hash;

  if ( variant_hash(dep, &hash, HASH_MURMUR) )
    return hash.murmur;

  assert(0);
  return false;
}


static idg_mdep *
new_mdep(DECL_LD term_t dep)
{ fastheap_term *r;

  if ( (r=term_to_fastheap(dep)) )
  { idg_mdep *mdep = malloc(sizeof(*mdep));

    if ( mdep )
    { memset(mdep, 0, sizeof(*mdep));
      mdep->magic      = IDG_MDEP_MAGIC;
      mdep->dependency = r;
      mdep->hash       = mdep_hash(dep);

      return mdep;
    }

    free_fastheap(r);
    PL_resource_error("memory");
  }

  return false;
}

static int
find_dep(DECL_LD idg_mdep *mdep, term_t dep, idg_mdep **found)
{ if ( mdep && mdep->magic == IDG_MDEP_MAGIC )
  { unsigned int hash = mdep_hash(dep);

    for(; mdep && mdep->magic == IDG_MDEP_MAGIC; mdep = mdep->next.dep)
    { if ( mdep->hash == hash )
      { term_t dep2;
	fid_t fid;

	if ( (fid=PL_open_foreign_frame()) )
	{ if ( (dep2=PL_new_term_ref()) &&
	       put_fastheap(mdep->dependency, dep2) )
	  { if ( is_variant_ptr(valTermRef(dep), valTermRef(dep2)) )
	    { *found = mdep;
	      return true;
	    }
	    PL_discard_foreign_frame(fid);
	    continue;
	  }
	}

	return -1;				/* error */
      }
    }
  }

  return false;
}


static
PRED_IMPL("$idg_forced", 1, idg_forced, 0)
{ trie *atrie;

  if ( get_trie(A1, &atrie) )
  { idg_node *n;

    if ( (n=atrie->data.IDG) )
      return !!n->force_reeval;
  }

  return false;
}

static void
free_mdep(idg_mdep *mdep)
{ assert(mdep->magic == IDG_MDEP_MAGIC);
  free_fastheap(mdep->dependency);
  dep_free_queue(mdep->queue);
  free(mdep);
}


/* Returns true if the queue went from empty to non-empty,
 * so we must propagate the IDG change event,
 */

static int
mdep_queue_answer(idg_mdep *mdep, word ans)
{ int rc;

  if ( !mdep->queue )
  { mdep->queue = allocHeapOrHalt(sizeof(*mdep->queue));
    initBuffer(mdep->queue);
  }

  if ( isAtom(ans) )
    PL_register_atom(word2atom(ans));

  rc = !isEmptyBuffer(mdep->queue);
  addBuffer(mdep->queue, ans, word);

  return rc;
}


static int
mdep_unify_answers(term_t t, idg_mdep *mdep)
{ GET_LD
  word *base = baseBuffer(mdep->queue, word);
  word *top  = topBuffer(mdep->queue, word);
  term_t tail = PL_copy_term_ref(t);
  term_t head = PL_new_term_ref();
  int count = 0;

  for(; base < top; base++)
  { if ( isAtom(*base) )
    { ClauseRef cref = clause_clref(word2atom(*base));

      if ( !ison(cref->value.clause, CL_ERASED) )
      { if ( !PL_unify_list(tail, head, tail) ||
	     !PL_unify_atom(head, word2atom(*base)) )
	  return -1;
	count++;
      }
    } else
    { trie_node *an = word2ptr(trie_node*, *base);

      if ( an->value )
      { if ( !PL_unify_list(tail, head, tail) ||
	     !PL_unify_pointer(head, an) )
	  return -1;
	count++;
      }
    }
  }

  if ( !PL_unify_nil(tail) )
    return -1;

  return count;
}


static void
mdep_empty_queue(idg_mdep *mdep, size_t del)
{ if ( mdep->queue && !isEmptyBuffer(mdep->queue) )
  { word *base = baseBuffer(mdep->queue, word);
    word *top;
    size_t left;

    if ( del != (size_t)-1 )
      top = base+del;
    else
      top = topBuffer(mdep->queue, word);

    for(; base < top; base++)
    { if ( isAtom(*base) )
	PL_unregister_atom(word2atom(*base));
    }

    left = topBuffer(mdep->queue, word) - top;

    if ( left == 0 )
    { emptyBuffer(mdep->queue, 512);
    } else
    { memmove(baseBuffer(mdep->queue, word), top,
	      left*sizeof(*base));
      seekBuffer(mdep->queue, left, word);
    }
  }
}

static void
mdep_empty_queues(idg_mdep *mdep)
{ while(mdep && mdep->magic == IDG_MDEP_MAGIC)
  { mdep_empty_queue(mdep, (size_t)-1);

    mdep = mdep->next.dep;
  }
}


static void
dep_free_queue(Buffer queue)
{ if ( queue )
  { word *base = baseBuffer(queue, word);
    word *top  = topBuffer(queue, word);

    for(; base < top; base++)
    { if ( isAtom(*base) )
	PL_unregister_atom(word2atom(*base));
    }

    discardBuffer(queue);
    freeHeap(queue, sizeof(*queue));
  }
}


/* - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - -
(*) See (*) with '$idg_add_dyncall'(+Variant):  we   need  to  clean the
falsecount on a call.
- - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - */

#define idg_add_monotonic_edge(src_trie, dst_trie, dep) LDFUNC(idg_add_monotonic_edge, src_trie, dst_trie, dep)
static int
idg_add_monotonic_edge(DECL_LD trie *src_trie, trie *dst_trie, term_t dep)
{ Definition def = dst_trie->data.predicate;
  idg_node *sn, *dn;

  if ( (sn=src_trie->data.IDG) &&
       (dn=dst_trie->data.IDG) )
  { if ( sn->monotonic && !sn->lazy )
      sn->falsecount = 0;			/* (*) */

    if ( def->tabling && ison(def->tabling, TP_MONOTONIC) )
      return idg_add_child(dn, sn, dep, def->tabling->flags);
    else
      return true;				/* monotonic --> incremental */
  }

  if ( def->tabling &&
       ison(def->tabling, TP_OPAQUE) )
    return true;				/* monotonic --> opaque */

  return idg_dependency_error_mono(src_trie, dst_trie);
}

/** '$idg_add_monotonic_dep'(+SrcTrie, +Dep, +TargetTrie)
 */

static
PRED_IMPL("$idg_add_monotonic_dep", 3, idg_add_monotonic_dep, 0)
{ PRED_LD
  trie *src_trie, *dst_trie;

  return ( get_trie(A1, &src_trie) &&
	   get_trie(A3, &dst_trie) &&
	   idg_add_monotonic_edge(src_trie, dst_trie, A2) );
}


/** '$idg_add_mono_<dyn_dep'(:Head, +Dependency, +TargetTrie)
 */

static
PRED_IMPL("$idg_add_mono_dyn_dep", 3, idg_add_mono_dyn_dep, 0)
{ PRED_LD
  trie *ctrie;
  Procedure proc;

  if ( get_procedure(A1, &proc, 0, GP_FIND) &&
       get_trie(A3, &ctrie) )
  { trie *atrie;

    if ( (atrie=trie_for_dynamic_predicate(proc->definition,
					   ctrie, A1)) )
    { return idg_add_monotonic_edge(atrie, ctrie, A2);
    }
  }

  return false;
}


/* - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - -
(*) We must increment the target falsecount  as otherwise it is possible
that all other changed dependents evaluate  to   the  same table and the
affected table is not updated.
- - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - */

static int
mono_idg_changed(trie *atrie, word answer)
{ idg_node *sn = atrie->data.IDG;
  TablePP aff;

  if ( sn && (aff=sn->affected) )
  { table_key_t k;
    table_value_t v;
    TableEnum en;

    en = newTableEnumPP(aff);
    while( advanceTableEnum(en, &k, &v) )
    { idg_node *dn = key2ptr(k);
      idg_mdep *mdep = val2ptr(v);
      int nonempty = 0;

      if ( dn->force_reeval )		/* Already marked as invalid */
      { dn->falsecount++;		/* see (*) */
	continue;
      }

      while ( mdep && mdep->magic == IDG_MDEP_MAGIC )
      { if ( mdep->lazy )
	{ nonempty += mdep_queue_answer(mdep, answer);
	  dn->lazy_queued = true;
	  DEBUG(MSG_TABLING_MONOTONIC,
		print_answer_table(dn->atrie,
				   "queued answer (nonempty=%d)", nonempty));
	}
	mdep = mdep->next.dep;
      }
      if ( !nonempty && (!dn->monotonic || dn->lazy) )
      { int flags = IDG_CHANGED_NODE;

	if ( dn->lazy )
	  flags |= IDG_CHANGED_MONO;
	if ( !idg_changed(dn->atrie, flags) )
	  return false;
      }
    }
    freeTableEnum(en);
  }

  return true;
}


static void
force_reeval(DECL_LD idg_node *n)
{ n->force_reeval = true;

  if ( LD->transaction.generation )
  { tt_add_table(n->atrie, TT_TBL_INVALIDATE);
    tt_abolish_table(n->atrie);			/* remove scheduled answers */
  }
}


/** '$tbl_monotonic_add_answer'(+Trie, +Answer) is semidet.
 *
 * Add an answer from  monotonic  propagation.   If we add a new value,
 * perform dynamic invalidation as if this was a dynamic predicate.
 *
 * @tbd  Implement the tripwires. Share code with
 *       '$tbl_wkl_add_answer'/4.
 */

static
PRED_IMPL("$tbl_monotonic_add_answer", 2, tbl_monotonic_add_answer, 0)
{ PRED_LD
  trie *atrie;

  if ( get_trie(A1, &atrie) )
  { if ( atrie->data.IDG && !atrie->data.IDG->monotonic )
    { Sdprintf("Monotonic propagation to non-monotonic table??\n");
      idg_changed(atrie, IDG_CHANGED_NODE);
      return false;
    } else if ( ison(atrie, TRIE_ISMAP) )	/* answer subsumption */
    { trie_node *node = wkl_mode_add_answer(NULL, atrie, A2, 0);

      if ( node )
      { mono_idg_changed(atrie, ptr2word(node));
	return true;
      }
    } else					/* normal tabling */
    { trie_node *node;
      Word kp = valTermRef(A2);
      int rc = trie_lookup_abstract(atrie, NULL, &node, kp,
				    true, NULL, NULL);

      if ( rc > 0 )
      { if ( node->value )
	  return false;
	tt_add_answer(atrie, node);
	set_trie_value_word(atrie, node, ATOM_trienode);

	if ( !mono_idg_changed(atrie, ptr2word(node)) )
	  return false;
	if ( !atrie_answer_event(atrie, node) )
	  return false;

	return true;
      } else
      { return trie_error(rc, A1);
      }
    }
  }

  return false;
}

static
PRED_IMPL("$tbl_propagate_start", 1, tbl_propagate_start, 0)
{ PRED_LD

  return PL_unify_integer(A1, LD->tabling.in_assert_propagation++);
}

static
PRED_IMPL("$tbl_propagate_end", 1, tbl_propagate_end, 0)
{ PRED_LD

  return PL_get_integer_ex(A1, &LD->tabling.in_assert_propagation);
}

/** '$tbl_collect_mono_dep' is semidet.
 *
 * True when we are either in monotonic propagation or the inner
 * tabled predicate is monotonic.  In this case the dynamic predicate
 * call must shift/1 to establish the dependency.
 */

static int
inner_is_monotonic(DECL_LD)
{ trie *dep;

  if ( LD->tabling.has_scheduling_component &&
       (dep=idg_current()) )
  { Definition def = dep->data.predicate;

    if ( def->tabling && ison(def->tabling, TP_MONOTONIC) )
      return true;
  }

  return false;
}


static
PRED_IMPL("$tbl_collect_mono_dep", 0, tbl_collect_mono_dep, 0)
{ PRED_LD

  if ( LD->tabling.in_assert_propagation )
    return true;

  return inner_is_monotonic();
}

/** '$mono_reeval_prepare'(+ATrie, -Size) is semidet.
 *
 *  Prepare  ATrie  for   lazy   monotonic    updates.   Together   with
 *  '$mono_reeval_done'/3, this should monitor whether   or not the trie
 *  has been modified. Without answer subsumption,  this is easy: as the
 *  trie is monotonic no answers  are  deleted   and  thus  the  trie is
 *  unchanged iff the `value_count` of the trie is unchanged.
 *
 *  With  answer  subsumption  this  is  harder  as  each  primary  node
 *  (`value_count`) has one secondary node (the _ModeArgs_) if no delays
 *  are involved. With delays  there  can   be  more,  but  as monotonic
 *  evaluation does not involve negation this is irrelevant to us.
 *
 *  We do however need to remember the final node.  We do so by marking
 *  this node using the flag TN_IDG_AS_LAST.
 */

static void *
mono_reeval_prep_node(trie_node *n, void *ctx)
{ if ( n->value && ison(n, TN_SECONDARY) )
    set(n, TN_IDG_AS_LAST);
  else
    clear(n, TN_IDG_AS_LAST);

  return NULL;
}

static
PRED_IMPL("$mono_reeval_prepare", 2, mono_reeval_prepare, 0)
{ PRED_LD
  trie *atrie;

  if ( get_trie(A1, &atrie) )
  { idg_node *idg = atrie->data.IDG;

    if ( idg && idg->falsecount && idg->monotonic && idg->lazy )
    { if ( LD->transaction.generation )
      { switch(tt_mono_status(atrie))
	{ case M_INVALID_DEPS:
	  case M_MIXED_CLAUSES:
	    tt_add_table(atrie, TT_TBL_INVALIDATE);
	    break;
	  case M_OLD_CLAUSES:
	    idg->tt_notrail = true;
	    break;
	  case M_NEW_CLAUSES:
	    idg->tt_notrail = false;
	    break;
	}
      }

      idg->lazy_queued = false;		/* trap that new answers are queued */
      idg->mono_reevaluating = true;
      idg->tt_new_dep = false;		/* see idg_add_child() */
      if ( ison(atrie, TRIE_ISMAP) )
	map_trie_node(&atrie->root, mono_reeval_prep_node, atrie);

      return PL_unify_integer(A2, atrie->value_count);
    }
  }

  return false;
}


/* - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - -
The answer subsumption trie may have   answers queued for affected nodes
that have already been deleted.
- - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - */

static void
prune_deleted_mdeps(idg_node *idg)
{ if ( idg->affected )
  { TableEnum en = newTableEnumPP(idg->affected);
    table_key_t k;
    table_value_t v;

    while(advanceTableEnum(en, &k, &v))
    { idg_node *dn = key2ptr(k);
      idg_mdep *mdep = val2ptr(v);

      if ( dn->force_reeval )			/* Invalidated; no queue */
      { dn->falsecount++;			/* see mono_idg_changed() */
	continue;
      }
      if ( !dn->lazy )				/* eager: no queue */
	continue;

      while( mdep && mdep->magic == IDG_MDEP_MAGIC )
      { if ( mdep->queue )
	{ word *base = baseBuffer(mdep->queue, word);
	  word *top  = topBuffer(mdep->queue, word);
	  word *out  = base;

	  for(; base < top; base++)
	  { if ( isAtom(*base) )
	    { *out++ = *base;
	    } else
	    { trie_node *an = word2ptr(trie_node *, *base);

	      if ( an->value )
		*out++ = *base;
	    }
	  }
	  mdep->queue->top = (void*)out;
	}

	mdep = mdep->next.dep;
      }
    }

    freeTableEnum(en);
  }
}


static void *
mono_reeval_done_node(trie_node *n, void *ctx)
{ int *gc = ctx;

  if ( n->value && ison(n, TN_SECONDARY) )
  { if ( ison(n, TN_IDG_AS_LAST) )
    { clear(n, TN_IDG_AS_LAST);
      return NULL;				/* same aggregated value */
    }
    return n;					/* new aggregated value */
  }
  if ( ison(n, TN_IDG_AS_LAST) )
  { clear(n, TN_IDG_AS_LAST);			/* deleted aggregated value */
    return n;
  }

  if ( is_leaf_trie_node(n) && !n->value )
    (*gc)++;

  return NULL;
}


/* - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - -
mono_scc_is_complete() validates that a lazy monotonic node is complete.
A lazy monotonic node is complete if none of its (recursively) dependent
lazy monotonic nodes has unprocessed  queued   answers  and there are no
incremental invalid nodes or "force_reeval" nodes in the dependencies.

If the SCC is complete, all  nodes  in   the  SCC  are  marked as valid.
Otherwise it returns the found invalid dependency.
- - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - */

typedef struct mono_scc_state
{ idg_node *idg;				/* current node */
  TableEnum en;					/* Enum on its dependencies */
  TablePW visited;				/* IDGNode -> bool */
  segstack  stack;				/* agenda */
  idg_node  *buf[100];
} mono_scc_state;


static int
mdep_is_empty(idg_mdep *mdep)
{ while ( mdep && mdep->magic == IDG_MDEP_MAGIC )
  { if ( mdep->queue && !isEmptyBuffer(mdep->queue) )
    { word *base = baseBuffer(mdep->queue, word);
      word *top  = topBuffer(mdep->queue, word);

      /* There may only be deleted answers in the queue. */
      /* see also mdep_unify_answers() */
      for(; base < top; base++)
      { if ( isAtom(*base) )
	{ ClauseRef cref = clause_clref(word2atom(*base));

	  if ( !ison(cref->value.clause, CL_ERASED) )
	    return false;
	} else
	{ trie_node *an = word2ptr(trie_node *, *base);

	  if ( an->value )
	    return false;
	}
      }
    }

    mdep = mdep->next.any;
  }

  return true;
}

#define mono_scc_is_complete_loop(state) \
	LDFUNC(mono_scc_is_complete_loop, state)

static idg_node *
mono_scc_is_complete_loop(DECL_LD mono_scc_state *state)
{ typedef struct idg_node *IDGNode;

  for(;;)
  { table_key_t k;
    table_value_t v;

    while(advanceTableEnum(state->en, &k, &v))
    { idg_node *dep = key2ptr(k);
      idg_mdep *mdep;

      if ( (mdep=lookupHTablePP(dep->affected, state->idg)) &&
	   !mdep_is_empty(mdep) )
      { DEBUG(MSG_TABLING_MONOTONIC,
	      print_answer_table(dep->atrie, "  queued answers"));
	return state->idg;
      }

      if ( dep->falsecount )
      { if ( !dep->monotonic || dep->force_reeval )
	{ DEBUG(MSG_TABLING_MONOTONIC,
		print_answer_table(dep->atrie, "  not monotonic or forced"));
	  return dep;
	}

	if ( dep->lazy && dep->dependent && dep->dependent->size > 0 &&
	     !lookupHTablePW(state->visited, dep) )
	{ if ( !pushSegStack(&state->stack, dep, IDGNode) )
	    outOfCore();
	  addHTablePW(state->visited, dep, true);
	}
      }
    }

    freeTableEnum(state->en);
    state->en = NULL;

    if ( popSegStack(&state->stack, &state->idg, IDGNode) )
    { state->en = newTableEnumPP(state->idg->dependent);
    } else
      break;
  }

  return NULL;
}


#define mono_scc_is_complete(idg) \
	LDFUNC(mono_scc_is_complete, idg)

static idg_node *
mono_scc_is_complete(DECL_LD idg_node *idg)
{ DEBUG(MSG_TABLING_MONOTONIC,
	print_answer_table(idg->atrie, "Checking completeness of monotonic SCC"));

  if ( idg->falsecount && idg->dependent && idg->dependent->size > 0 )
  { mono_scc_state state;
    idg_node *invalid;

    state.idg = idg;
    state.visited = newHTablePW(4);
    addHTablePW(state.visited, idg, true);
    initSegStack(&state.stack, sizeof(idg_node*), sizeof(state.buf), state.buf);

    state.en = newTableEnumPP(idg->dependent);
    invalid = mono_scc_is_complete_loop(&state);
    if ( state.en )
      freeTableEnum(state.en);

    clearSegStack(&state.stack);
    if ( !invalid )
    { FOR_TABLE(state.visited, k, v)
      { idg_node *dep = key2ptr(k);
	(void) v;

	dep->falsecount = 0;
	dep->tt_notrail = false;
      }
    }
    destroyHTablePW(state.visited);

    return invalid;
  }

  return NULL;
}

#define has_queued_answers(idg) LDFUNC(has_queued_answers, idg)
static int
has_queued_answers(DECL_LD idg_node *idg)
{ int queued = false;

  if ( idg->dependent && idg->dependent->size > 0 )
  { TableEnum en = newTableEnumPP(idg->dependent);
    table_key_t k;
    table_value_t v;

    while( !queued && advanceTableEnum(en, &k, &v) )
    { idg_node *dep = key2ptr(k);
      idg_mdep *mdep;

      if ( (mdep=lookupHTablePP(dep->affected, idg)) &&
	   !mdep_is_empty(mdep) )
	queued = true;
    }

    freeTableEnum(en);
  }

  return queued;
}


/* - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - -
Count the invalid dependencies and return a   list of the lazy monotonic
ones that have pending answers and  the invalid non-lazy-monotonic ones.
This is the list of nodes that are ready to be evaluated.
- - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - */

#define invalid_dependencies(deps, idg, count) \
	LDFUNC(invalid_dependencies, deps, idg, count)

static int
invalid_dependencies(DECL_LD term_t deps, idg_node *idg, size_t *count)
{ term_t head = 0;
  term_t tail = 0;
  size_t cnt = 0;

  if ( idg->dependent && idg->dependent->size > 0 )
  { TableEnum en = newTableEnumPP(idg->dependent);
    table_key_t k;
    table_value_t v;

    while(advanceTableEnum(en, &k, &v))
    { idg_node *dep = key2ptr(k);

      if ( dep->falsecount > 0 )
      { cnt++;

	if ( (dep->monotonic && !dep->force_reeval && has_queued_answers(dep)) ||
	     !(dep->monotonic && !dep->force_reeval) )
	{ if ( head == 0 )
	  { tail = PL_copy_term_ref(deps);
	    head = PL_new_term_ref();
	  }

	  if ( !PL_unify_list(tail, head, tail) ||
	       !PL_unify_atom(head, trie_symbol(dep->atrie)) )
	  { freeTableEnum(en);
	    return false;
	  }
	}
      }
    }
    freeTableEnum(en);
  }

  *count = cnt;

  if ( cnt == 0 )
  { if ( idg->lazy_queued )
      return PL_unify_atom(deps, ATOM_false);
    else
      return PL_unify_nil(deps);
  } else
  { return PL_unify_nil(tail ? tail : deps);
  }
}


/** '$mono_reeval_done'(+ATrie, +SizeAtStart, -InvalidDependencies)
 *
 * We are done processing queues answers  towards ATrie. This only means
 * we are done if there are no  more invalid dependencies. We return the
 * invalid dependencies of this node   such that reeval_monotonic_node/2
 * can restart the work on the dependencies if these exist.
 */

static
PRED_IMPL("$mono_reeval_done", 3, mono_reeval_done, 0)
{ PRED_LD
  trie *atrie;
  int vc;

  if ( get_trie(A1, &atrie) &&
       PL_get_integer(A2, &vc) )
  { idg_node *idg;
    int rc = true;

    if ( (idg=atrie->data.IDG) )
    { size_t invalid_deps;
      term_t deps_t = PL_new_term_ref();

      idg->mono_reevaluating = false;
      if ( idg->tt_new_dep )
	tt_add_table(atrie, TT_TBL_INVALIDATE);
      if ( !invalid_dependencies(deps_t, idg, &invalid_deps) )
	return false;

      if ( atrie->value_count == vc )
      { trie_node *n = NULL;

	DEBUG(MSG_TABLING_MONOTONIC,
	      print_answer_table(atrie, "%d answers (same)", vc));

	if ( ison(atrie, TRIE_ISMAP) )
	{ int gc = 0;
	  int queue;

	  n = map_trie_node(&atrie->root, mono_reeval_done_node, &gc);
	  queue = (n && n->value != 0);
	  if ( gc )
	  { prune_deleted_mdeps(idg);
	    prune_trie(atrie, &atrie->root, NULL, NULL);
	  }
	  if ( queue )
	    rc = mono_idg_changed(atrie, ptr2word(n));
	}

	if ( !n && rc && !invalid_deps )
	  rc = !idg_propagate_change(idg, 0);
      } else
      { DEBUG(MSG_TABLING_MONOTONIC,
	      print_answer_table(atrie, "%d new answers",
				 atrie->value_count - vc));
      }

      if ( invalid_deps + idg->lazy_queued )
      { idg_node *invalid;

	if ( (invalid=mono_scc_is_complete(idg)) == NULL )
	{ rc = PL_unify_nil(A3);
	} else
	{ idg->falsecount = invalid_deps + idg->lazy_queued;
	  if ( PL_get_nil(deps_t) )
	  { term_t t2;

	    rc = ( (t2=PL_new_term_ref()) &&
		    PL_put_atom(t2, trie_symbol(invalid->atrie)) &&
		   PL_cons_list(deps_t, t2, deps_t) &&
		   PL_unify(A3, deps_t) );
	  } else
	  { rc = PL_unify(A3, deps_t);
	  }
	}
      } else
      { idg->falsecount = 0;
	idg->tt_notrail = false;
	rc = PL_unify_nil(A3);
      }
    }

    return rc;
  }

  return false;
}

static
PRED_IMPL("$idg_mono_empty_queue", 2, idg_mono_empty_queue, 0)
{ PRED_LD
  idg_mdep *mdep;
  size_t del;

  if ( PL_get_pointer_ex(A1, (void**)&mdep ) &&
       mdep->magic == IDG_MDEP_MAGIC &&
       PL_get_size_ex(A2, &del) )
  { mdep_empty_queue(mdep, del);

    return true;
  }

  return false;
}


/** '$idg_mono_invalidate'(+Trie) is det.
 *
 *  Invalidate dependent tables after erasing a clause.  This
 *
 *    - Propagates falsecount as usual
 *    - Sets `force_reeval` on any monotonic node
 *    - Empties monotonic answer queues
 */

static
PRED_IMPL("$idg_mono_invalidate", 1, idg_mono_invalidate, 0)
{ trie *atrie;

  if ( get_trie(A1, &atrie) )
    return idg_changed(atrie, IDG_CHANGED_NODE);

  return false;
}


		 /*******************************
		 *    LAZY MONOTONIC TABLING	*
		 *******************************/

/** '$mono_idg_changed'(+ATrie, +Answer)
 *
 *  A new answer was produced  for  ATrie,   which  is  either  a normal
 *  monotonic answer trie or the  psuedo   trie  for a dynamic predicate
 *  call variant. In the first case Answer  is a trie node (integer), in
 *  the second it is a clause reference (blob).
 *
 *  Our task is to record the answer with the dependencies that point at
 *  lazy monotonic tables and to mark   dependent tries as invalid using
 *  the same logic as we use for incremental tabling.
 */

#define get_mono_answer(t, ap) LDFUNC(get_mono_answer, t, ap)
static word
get_mono_answer(DECL_LD term_t t, word *ap)
{ if ( *ap == 0 )
  { Word p = valTermRef(t);

    deRef(p);
    if ( isAtom(*p) )			/* clause reference */
    { *ap = *p;
    } else if ( isInteger(*p) )		/* trie node */
    { *ap = ptr2word(word_to_answer(*p));
    } else
      return PL_type_error("tbl_answer", t);
  }

  return *ap;
}


static int
mono_queue_answer(DECL_LD trie *atrie, term_t ans, word an)
{ get_mono_answer(ans, &an);

  return mono_idg_changed(atrie, an);
}


static
PRED_IMPL("$mono_idg_changed", 2, mono_idg_changed, 0)
{ PRED_LD
  trie *atrie;

  if ( get_trie(A1, &atrie) )
    return mono_queue_answer(atrie, A2, 0);

  return false;
}


		 /*******************************
		 *  INCREMENTAL RE-EVALUATION	*
		 *******************************/

/** '$tbl_reeval_wait'(+Trie, -Status) is det.
 *
 * Get the status for Trie as one of `dynamic`, `monotonic`, `complete`
 * or `invalid`, but wait if another thread is evaluating the table.
 *
 * @error `deadlock` if claiming the table would cause a deadlock.
 */

static atom_t
table_status_reeval_wait(DECL_LD trie *atrie)
{ idg_node *n;

  if ( (n=atrie->data.IDG) )
  { if ( atrie->data.worklist == WL_DYNAMIC )
    { return ATOM_dynamic;
    } else if ( n->falsecount > 0 && n->lazy )
    { return ATOM_invalid;
    } else if (	n->monotonic )
    { return ATOM_monotonic;
    } else
    {
#ifdef O_PLMT
      int tid = PL_thread_self();

      if ( atrie->tid == tid )			/* remain owner */
      { return table_status(atrie);
      } else
      { atom_t status;

	if ( !claim_answer_table(atrie, NULL, 0) )
	  return false;				/* deadlock */

	status = table_status(atrie);
	COMPLETE_WORKLIST(atrie, (void)0);
	return status;
      }
#else
      return table_status(atrie);
#endif
    }
  }

  return 0;
}



static
PRED_IMPL("$tbl_reeval_wait", 2, tbl_reeval_wait, 0)
{ GET_LD
  trie *atrie;
  atom_t status;

  if ( get_trie(A1, &atrie) &&
       (status=table_status_reeval_wait(atrie)) )
    return PL_unify_atom(A2, status);

  return false;
}


/** '$tbl_reeval_prepare'(+Trie, -Variant, -Clause) is det.
 *
 * Prepare Trie for re-evaluation. If Trie is invalid, it is claimed and
 * prepared for re-evaluation and Variant is   unified  with the goal to
 * re-evaluate. If the Trie is (already)   valid,  unify Clause with its
 * answer set.
 *
 * If the trie is a monotonic  table  we   already  did  all the work in
 * reeval_lazy_monotonic_path/3, so we can  simple   set  the falsecount
 * back to 0.
 *
 * @error `deadlock` if claiming the table would cause a deadlock.
 */

static void *
reeval_prep_node(trie_node *n, void *ctx)
{ trie *atrie = ctx;

  if ( n->value )
  { set(n, TN_IDG_DELETED);
    clear(n, TN_IDG_ADDED);

    if ( answer_is_conditional(n) )
    { destroy_delay_info(atrie, n, true);
      n->data.delayinfo = NULL;
      clear(n, TN_IDG_UNCONDITIONAL);
    } else
    { set(n, TN_IDG_UNCONDITIONAL);
    }
  }

  return NULL;
}


/** '$tbl_reeval_prepare_top'(+Atrie, -Clause) is det.
 *
 *   Start reevaluation for Atrie because it is invalid.  This binds
 *   Clause if the reevaluation was already done.  Else the trie is
 *   prepared for reevaluation.
 */

#define prepare_reeval(atrie) LDFUNC(prepare_reeval, atrie)
static int
prepare_reeval(DECL_LD trie *atrie)
{ idg_node *idg = atrie->data.IDG;
  worklist *wl  = atrie->data.worklist;

  DEBUG(MSG_TABLING_IDG_REEVAL,
	print_answer_table(atrie, "Preparing reeval of"));

  if ( tt_has_modified_dependencies(atrie) )
    tt_add_table(atrie, TT_TBL_INVALIDATE);

  idg->answer_count = atrie->value_count;
  idg->new_answer = false;
  idg->falsecount = 0;
  idg_clean_dependent(idg);
  if ( !idg->aborted )
    map_trie_node(&atrie->root, reeval_prep_node, atrie);
  idg->reevaluating = true;

  if ( WL_IS_WORKLIST(wl) )
  { wl->negative    = false;
    wl->has_answers = false;
    wl->neg_delayed = false;
  }

  return true;
}

static
PRED_IMPL("$tbl_reeval_prepare_top", 2, tbl_reeval_prepare_top, 0)
{ PRED_LD
  trie *atrie;

  if ( get_trie(A1, &atrie) )
  { idg_node *idg = atrie->data.IDG;

#ifdef O_PLMT
    if ( ison(atrie, TRIE_ISSHARED) )
    { atom_t cref = 0;

      if ( !claim_answer_table(atrie, &cref, 0) )
	return false;				/* deadlock */
      if ( cref )
	return PL_unify_atom(A2, cref);
    }
#endif

    if ( idg->falsecount == 0 && !idg->force_reeval) /* someone else re-evaluated it */
    { if ( ison(atrie, TRIE_ISMAP) )
	return PL_unify_integer(A2, 0);
      else
	return PL_unify_atom(A2, trie_symbol(atrie));
    }

    return prepare_reeval(atrie);
  }

  return false;
}

/** '$tbl_reeval_prepare'(+Atrie, -Variant) is semidet.
 *
 *  Prepare reevaluation of a node on a false path.  Succeeds if Atrie
 *  still needs reevaluation (preparing for this) and bind Variant to
 *  the goal that needs to be reevaluated.
 */

static
PRED_IMPL("$tbl_reeval_prepare", 2, tbl_reeval_prepare, 0)
{ PRED_LD
  trie *atrie;

  if ( get_trie(A1, &atrie) )
  { idg_node *idg = atrie->data.IDG;

    if ( idg->monotonic && !idg->force_reeval )
      return false;

#ifdef O_PLMT
    if ( ison(atrie, TRIE_ISSHARED) )
    { atom_t cref = 0;

      if ( !claim_answer_table(atrie, &cref, 0) )
	return false;				/* deadlock */
      if ( cref )
	return PL_unify_atom(A3, cref);
    }
#endif

    if ( idg->falsecount == 0 )			/* someone else re-evaluated it */
      return false;

    if ( !unify_trie_term(atrie->data.variant, NULL, A2) )
      return false;

    return prepare_reeval(atrie);
  }

  return false;
}


/** '$tbl_reeval_abandon'(+ATrie)
 *
 * Release ownership of ATrie if we cannot re-evaluate it
 */

static
PRED_IMPL("$tbl_reeval_abandon", 1, tbl_reeval_abandon, 0)
{ trie *atrie;

  if ( get_trie(A1, &atrie) )
  { DEBUG(MSG_TABLING_SHARED,
	  print_answer_table(atrie, "Abondon re-evaluation"));
    COMPLETE_WORKLIST(atrie, (void)0);

    return true;
  }

  return false;
}


static void *
reeval_complete_node(trie_node *n, void *ctx)
{ trie *atrie = ctx;
#ifdef O_DEBUG
  const char *action = NULL;
#endif

  if ( !n->value )
  { clear(n, TN_IDG_MASK);
    return NULL;
  }

  if ( ison(n, TN_IDG_DELETED) )
  { clear(n, TN_IDG_DELETED);		/* not used by trie admin */
    trie_delete(atrie, n, false);	/* TBD: can we prune? */
    if ( isoff(n, TN_IDG_UNCONDITIONAL) )
      simplify_answer(atrie->data.worklist, n, false);
    DEBUG(MSG_TABLING_IDG_REEVAL_NODE, action = "Not reappeared");
  } else if ( ison(n, TN_IDG_UNCONDITIONAL) &&
	      answer_is_conditional(n) )
  { atrie->data.IDG->new_answer = true;
    DEBUG(MSG_TABLING_IDG_REEVAL_NODE, action = "Got conditional");
  } else if ( isoff(n, TN_IDG_UNCONDITIONAL) &&
	      !answer_is_conditional(n) )
  { atrie->data.IDG->new_answer = true;
    DEBUG(MSG_TABLING_IDG_REEVAL_NODE, action = "Got UNconditional");
  } else
  { DEBUG(MSG_TABLING_IDG_REEVAL_NODE, action = "Not modified");
  }

  DEBUG(MSG_TABLING_IDG_REEVAL_NODE,
	print_answer(action, n));

  clear(n, TN_IDG_MASK);

  return NULL;
}


static void
reeval_complete(trie *atrie)
{ idg_node *n;

  if ( (n=atrie->data.IDG) && n->reevaluating )
  { int same_answers;
    map_trie_node(&atrie->root, reeval_complete_node, atrie);

    same_answers = ( n->new_answer == false &&
		     n->answer_count == atrie->value_count );

    DEBUG(MSG_TABLING_IDG_REEVAL,
	  print_answer_table(atrie,
			     "Completed reeval of (modified: %s (new: %s, Danswers = %zd))",
			     same_answers ? "false" : "true",
			     n->new_answer ? "true" : "false",
			     (size_t)(atrie->value_count - n->answer_count)));

    if ( same_answers )
      idg_propagate_change(n, 0);
    else
      trie_discard_clause(atrie);

    TRIE_STAT_INC(n, reevaluated);

    n->force_reeval = false;
    n->aborted      = false;
  }
}


/* - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - -
reset_reevaluation(trie *atrie)

Reset a table that is  being   reevaluated  while an exception happened.
This must ensure that a subsequent call   on  the table will restart the
re-evaluation and forward a _not-changed_ to   the affected nodes if the
table evaluates to the same values.

We set the nodes back to the   state  after the initial preparation. The
flag `aborted` is used by  the  subsequent   prepare  to  keep  the node
states.

TBD: the dependency links  to  dependent   nodes  (and  back)  have been
removed during preparation. This is ok for restoring the state. It poses
problems for propagating the falsecounts from our dependent nodes to our
affected nodes though if there are  modifications to our dependent nodes
while re-evaluation is in progress.  In-progress   here  means  the time
between the node was prepared and completed.  This period can be long if
the re-evaluation has been aborted.
- - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - */

static void *
reset_evaluate_node(trie_node *n, void *ctx)
{ trie *atrie = ctx;

  if ( answer_is_conditional(n) )
  { destroy_delay_info(atrie, n, true);
    n->data.delayinfo = NULL;
  }

  if ( ison(n, TN_IDG_ADDED) )
  { trie_delete(atrie, n, false);	/* we are enumerating this node */
  } else				/* and cannot delete it (now) */
  { set(n, TN_IDG_DELETED);
  }

  return NULL;
}


static void
reset_reevaluation(trie *atrie)
{ idg_node *n = atrie->data.IDG;

  DEBUG(MSG_TABLING_EXCEPTION,
	print_answer_table(atrie, "Abort reevaluation of (%zd answers)",
			   atrie->value_count));

  map_trie_node(&atrie->root, reset_evaluate_node, atrie);
  assert(n->answer_count == atrie->value_count);

  n->new_answer = false;
  n->aborted = true;
  n->falsecount = 1;
  set(atrie, TRIE_COMPLETE);
  COMPLETE_WORKLIST(atrie, n->reevaluating = false);
}


		 /*******************************
		 *	      EVENTS		*
		 *******************************/

/* - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - -
Send an event for a new answer. Returns  false if the event hooks raised
an exception, i.e., failure is silently ignored.
- - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - */

static int
atrie_answer_event(DECL_LD trie *atrie, trie_node *answer)
{ Definition def;

  if ( (def=atrie->data.predicate) &&
       def->events )
  { term_t wrapper, skel;

    if ( (wrapper=PL_new_term_ref()) &&
	 (skel=PL_new_term_ref()) &&
	 unify_skeleton(atrie, wrapper, skel) &&
	 unify_trie_term(answer, NULL, skel) )
    { if ( table_answer_event(atrie->data.predicate,
			      ATOM_new_answer, wrapper) )
	return true;
      else
	return !PL_exception(0);
    }
  }

  return true;
}


		 /*******************************
		 *	      FLAGS		*
		 *******************************/

int
setMonotonicMode(atom_t a)
{ GET_LD

  if ( a == ATOM_eager )
    clear(&LD->tabling, TF_MONOTONIC_LAZY);
  else if ( a == ATOM_lazy )
    set(&LD->tabling, TF_MONOTONIC_LAZY);
  else
  { term_t value = PL_new_term_ref();

    PL_put_atom(value, a);
    return PL_error(NULL, 0, NULL, ERR_DOMAIN, ATOM_table_monotonic, value);
  }

  return true;
}



		 /*******************************
		 *	     RESTRAINTS		*
		 *******************************/

int
tbl_is_predicate_attribute(atom_t key)
{ return ( key == ATOM_abstract ||
	   key == ATOM_subgoal_abstract ||
	   key == ATOM_answer_abstract ||
	   key == ATOM_max_answers ||
	   key == ATOM_monotonic ||
	   key == ATOM_incremental ||
	   key == ATOM_tshared ||
	   key == ATOM_opaque ||
	   key == ATOM_lazy ||
	   key == ATOM_tabled
	 );
}


static void
clear_table_props(table_props *p)
{ p->flags            = 0;
  p->abstract         = (size_t)-1;
  p->subgoal_abstract = (size_t)-1;
  p->answer_abstract  = (size_t)-1;
  p->max_answers      = (size_t)-1;
  p->lazy_queue	      = NULL;
}


void
tbl_reset_tabling_attributes(Definition def)
{ table_props *p;

  if ( (p=def->tabling) )
    clear_table_props(p);
}


int
tbl_get_predicate_attribute(Definition def, atom_t att, term_t value)
{ table_props *p;

  if ( (p=def->tabling) )
  { GET_LD

    if ( att == ATOM_monotonic )
    { return PL_unify_integer(value, !!ison(p, TP_MONOTONIC));
    } else if ( att == ATOM_incremental )
    { return PL_unify_integer(value, !!ison(p, TP_INCREMENTAL));
    } else if ( att == ATOM_tshared )
    { return PL_unify_integer(value, !!ison(p, TP_SHARED));
    } else if ( att == ATOM_opaque )
    { return PL_unify_integer(value, !!ison(p, TP_OPAQUE));
    } else if ( att == ATOM_lazy )
    { return PL_unify_integer(value, !!ison(p, TP_LAZY));
    } else if ( att == ATOM_tabled )
    { return PL_unify_integer(value, !!ison(p, TP_TABLED));
    } else
    { size_t v0;

      if ( att == ATOM_abstract )
	v0 = p->abstract;
      else if ( att == ATOM_subgoal_abstract )
	v0 = p->subgoal_abstract;
      else if ( att == ATOM_answer_abstract )
	v0 = p->answer_abstract;
      else if ( att == ATOM_max_answers )
	v0 = p->max_answers;
      else
	return -1;

      if ( v0 != (size_t)-1 )
	return PL_unify_int64(value, v0);
    }
  }

  return false;
}


#define get_size_or_inf(t, vp) LDFUNC(get_size_or_inf, t, vp)
static int
get_size_or_inf(DECL_LD term_t t, size_t *vp)
{ size_t v;
  atom_t inf;

  if ( PL_get_atom(t, &inf) && inf == ATOM_infinite )
    v	= (size_t)-1;
  else if ( !PL_get_size_ex(t, &v) )
    return false;

  *vp = v;
  return true;
}


void
tbl_set_incremental_predicate(Definition def, int val)
{ table_props *p = get_predicate_table_props(def);
  int now = !!ison(p, TP_INCREMENTAL);

  if ( !!val != now )
  { if ( val )
      set(p, TP_INCREMENTAL);
    else
      clear(p, TP_INCREMENTAL);

    freeCodesDefinition(def, true);
  }
}


static int
set_bool_attr(Definition def, unsigned int flag, term_t value)
{ int v;

  if ( PL_get_bool_ex(value, &v) )
  { if ( flag == TP_INCREMENTAL )
    { tbl_set_incremental_predicate(def, v);

      return true;
    } else
    { table_props *props = get_predicate_table_props(def);

      if ( v )
	set(props, flag);
      else
	clear(props, flag);

      return true;
    }
  }

  return false;
}


static table_props *
get_predicate_table_props(Definition def)
{ table_props *p;

  if ( !(p=def->tabling) )
  { p = allocHeapOrHalt(sizeof(*p));

    clear_table_props(p);
    if ( !COMPARE_AND_SWAP_PTR(&def->tabling, NULL, p) )
    { p = def->tabling;
      freeHeap(p, sizeof(*p));
    }
  }

  return p;
}


int
tbl_set_predicate_attribute(Definition def, atom_t att, term_t value)
{ GET_LD

  if ( att == ATOM_monotonic )
  { return set_bool_attr(def, TP_MONOTONIC, value);
  } else if ( att == ATOM_incremental )
  { return set_bool_attr(def, TP_INCREMENTAL, value);
  } else if ( att == ATOM_tshared )
  { return set_bool_attr(def, TP_SHARED, value);
  } else if ( att == ATOM_opaque )
  { return set_bool_attr(def, TP_OPAQUE, value);
  } else if ( att == ATOM_lazy )
  { return set_bool_attr(def, TP_LAZY, value);
  } else if ( att == ATOM_tabled )
  { return set_bool_attr(def, TP_TABLED, value);
  } else
  { table_props *p = get_predicate_table_props(def);
    size_t v;

    if ( !get_size_or_inf(value, &v) )
      return false;

    if ( att == ATOM_abstract )
      p->abstract = v;
    else if ( att == ATOM_subgoal_abstract )
      p->subgoal_abstract = v;
    else if ( att == ATOM_answer_abstract )
      p->answer_abstract = v;
    else if ( att == ATOM_max_answers )
      p->max_answers = v;
    else
      return false;
  }

  return true;
}


int
tbl_is_restraint_flag(atom_t key)
{ return ( key == ATOM_max_table_subgoal_size_action ||
	   key == ATOM_max_table_subgoal_size ||
	   key == ATOM_max_table_answer_size_action ||
	   key == ATOM_max_table_answer_size ||
	   key == ATOM_max_answers_for_subgoal_action ||
	   key == ATOM_max_answers_for_subgoal );
}


static int
unify_restraint(term_t t, size_t val)
{ if ( val == (size_t)-1 )
    return false;
  else
    return PL_unify_uint64(t, val);
}


int
tbl_get_restraint_flag(DECL_LD term_t t, atom_t key)
{ if ( key == ATOM_max_table_subgoal_size_action )
    return PL_unify_atom(t, LD->tabling.restraint.max_table_subgoal_size_action);
  else if ( key == ATOM_max_table_answer_size_action )
    return PL_unify_atom(t, LD->tabling.restraint.max_table_answer_size_action);
  else if ( key == ATOM_max_answers_for_subgoal_action )
    return PL_unify_atom(t, LD->tabling.restraint.max_answers_for_subgoal_action);
  else if ( key == ATOM_max_table_subgoal_size )
    return unify_restraint(t, LD->tabling.restraint.max_table_subgoal_size);
  else if ( key == ATOM_max_table_answer_size )
    return unify_restraint(t, LD->tabling.restraint.max_table_answer_size);
  else if ( key == ATOM_max_answers_for_subgoal )
    return unify_restraint(t, LD->tabling.restraint.max_answers_for_subgoal);
  else
    return -1;
}


#define set_restraint_action(t, key, valp) LDFUNC(set_restraint_action, t, key, valp)
static int
set_restraint_action(DECL_LD term_t t, atom_t key, atom_t *valp)
{ atom_t act;

  if ( PL_get_atom_ex(t, &act) )
  { if ( act == ATOM_error || act == ATOM_warning || act == ATOM_suspend )
    { ok:
      *valp = act;
      return true;
    }

    if ( act == ATOM_complete_soundly )	/* XSB compatibility */
      act = ATOM_bounded_rationality;

    if ( key == ATOM_max_table_subgoal_size_action &&
	 ( act == ATOM_abstract ) )
      goto ok;
    if ( key == ATOM_max_table_answer_size_action &&
	 ( act == ATOM_bounded_rationality ||
	   act == ATOM_fail) )
      goto ok;
    if ( key == ATOM_max_answers_for_subgoal_action &&
	 ( act == ATOM_bounded_rationality ) )
      goto ok;

    return PL_domain_error("restraint_action", t);
  }

  return false;
}


static int
set_restraint(term_t t, size_t *valp)
{ GET_LD
  atom_t inf;

  if ( PL_get_atom(t, &inf) && inf == ATOM_infinite )
  { *valp = (size_t)-1;
    return true;
  }
  return PL_get_size_ex(t, valp);
}


int
tbl_set_restraint_flag(DECL_LD term_t t, atom_t key)
{ if ( key == ATOM_max_table_subgoal_size_action )
    return set_restraint_action(
	       t, key,
	       &LD->tabling.restraint.max_table_subgoal_size_action);
  else if ( key == ATOM_max_table_answer_size_action )
    return set_restraint_action(
	       t, key,
	       &LD->tabling.restraint.max_table_answer_size_action);
  else if ( key == ATOM_max_answers_for_subgoal_action )
    return set_restraint_action(
	       t, key,
	       &LD->tabling.restraint.max_answers_for_subgoal_action);
  else if ( key == ATOM_max_table_subgoal_size )
    return set_restraint(t, &LD->tabling.restraint.max_table_subgoal_size);
  else if ( key == ATOM_max_table_answer_size )
    return set_restraint(t, &LD->tabling.restraint.max_table_answer_size);
  else if ( key == ATOM_max_answers_for_subgoal )
    return set_restraint(t, &LD->tabling.restraint.max_answers_for_subgoal);
  else
    return -1;
}


static atom_t
tripwire_answers_for_subgoal(DECL_LD worklist *wl)
{ table_props *ps;
  size_t limit;

  if ( ((ps=wl->predicate->tabling) &&
	(limit=ps->max_answers) != (size_t)-1) )
  { if ( wl->table->value_count >= limit )
      return ATOM_bounded_rationality;
    return NULL_ATOM;
  }

  if ( (limit=LD->tabling.restraint.max_answers_for_subgoal) != (size_t)-1 )
  { if ( wl->table->value_count == limit )
      return LD->tabling.restraint.max_answers_for_subgoal_action;
  }

  return NULL_ATOM;
}


/* Create the most general ret/N term compliant with `spec`.  We need
 * this term when the answer count restraint is exceeded.
 */

static int
generalise_answer_substitution(DECL_LD term_t spec, term_t gen)
{ Word p = valTermRef(spec);

  deRef(p);
  if ( isTerm(*p) )
    return PL_unify_functor(gen, functorTerm(*p));
  if ( *p == ATOM_ret )
    return PL_unify_atom(gen, ATOM_ret);

  return PL_type_error("answer_substitution", spec);
}


/* Add the condition `answer_count_restraint` to the current delay list.
 * We can simply call the predicate as the constraint will be added to
 * the global delay list as a result.
 */


static int
add_answer_count_restraint(void)
{ predicate_t pred;

  pred = _PL_predicate("answer_count_restraint", 0, "system",
		       &GD->procedures.answer_count_restraint0);

  DEBUG(MSG_TABLING_RESTRAINT,
	Sdprintf("Calling %s\n", procedureName(pred)));

  return PL_call_predicate(NULL, PL_Q_PASS_EXCEPTION, pred, 0);
}


static int
add_radial_restraint(void)
{ predicate_t pred;

  pred = _PL_predicate("radial_restraint", 0, "system",
		       &GD->procedures.radial_restraint0);

  DEBUG(MSG_TABLING_RESTRAINT,
	Sdprintf("Calling %s\n", procedureName(pred)));

  return PL_call_predicate(NULL, PL_Q_PASS_EXCEPTION, pred, 0);
}


static int
tbl_wl_tripwire(worklist *wl, atom_t action, atom_t wire)
{ GET_LD
  predicate_t pred;
  term_t av;

  pred = _PL_predicate("tripwire", 3, "$tabling", &GD->procedures.tripwire3);

  DEBUG(MSG_TABLING_RESTRAINT,
	Sdprintf("Calling %s\n", procedureName(pred)));

  return ( (av = PL_new_term_refs(3)) &&
	   PL_put_atom(av+0, wire) &&
	   PL_put_atom(av+1, action) &&
	   PL_put_atom(av+2, trie_symbol(wl->table)) &&
	   PL_call_predicate(NULL, PL_Q_PASS_EXCEPTION, pred, av) );
}


static int
tbl_pred_tripwire(Definition def, atom_t action, atom_t wire)
{ GET_LD
  predicate_t pred;
  term_t av;

  pred = _PL_predicate("tripwire", 3, "$tabling", &GD->procedures.tripwire3);

  DEBUG(MSG_TABLING_RESTRAINT,
	Sdprintf("Calling %s\n", procedureName(pred)));

  return ( (av = PL_new_term_refs(3)) &&
	   PL_put_atom(av+0, wire) &&
	   PL_put_atom(av+1, action) &&
	   unify_definition(MODULE_user, av+2, def, 0, GP_QUALIFY) &&
	   PL_call_predicate(NULL, PL_Q_PASS_EXCEPTION, pred, av) );
}

		 /*******************************
		 *	    CONCURRENCY		*
		 *******************************/

#if O_PLMT

static int
table_needs_work(trie *atrie)
{ if ( ison(atrie, TRIE_COMPLETE) )
  { idg_node *n;

    if ( (n=atrie->data.IDG) )
    { if ( n->falsecount > 0 ||		/* invalid */
	   n->reevaluating )		/* fresh (re-evaluating) */
	return true;
    }

    return false;
  }

  return true;
}


/* - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - -
Claim ownership for an answer table if the table is incomplete/invalid:

  - If we alread own the table, fine
  - Else
    - If the table is incomplete, someone else is completing it
      (otherwise we were the owner).  Either throw a `deadlock`
      exception or wait.
    - If the table needs work (fresh, invalid), try to claim it.
    - If the table is complete, return its compiled trie.  As
      we are in a locked region we can do so safely.

Note that this code uses  a   mutex/condition  variable  pair. Currently
there is a single mutex. Future versions could  use an array of these to
reduce contention.
- - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - */

static int
claim_answer_table(DECL_LD trie *atrie, atom_t *clrefp, int flags)
{ if ( ison(atrie, TRIE_ISSHARED) && !(flags&AT_NOCLAIM) )
  { int mytid = PL_thread_self();
    volatile atom_t clref = 0;

    if ( atrie->tid != mytid )
    { LOCK_SHARED_TABLE(atrie);
    retry_shared:
      if ( atrie->tid )
      { register_waiting(mytid, atrie);
	if ( is_deadlock(atrie) )
	{ term_t ex;

	  DEBUG(MSG_TABLING_SHARED,
		print_answer_table(atrie, "DEADLOCK"));
	  unregister_waiting(mytid, atrie);
	  if ( (ex = PL_new_term_ref()) &&
	       PL_put_atom(ex, ATOM_deadlock) )
	    PL_raise_exception(ex);
	  UNLOCK_SHARED_TABLE(atrie);
	  return false;
	}
	TRIE_STAT_INC(atrie, wait);
	if ( !wait_for_table_to_complete(atrie) )
	{ UNLOCK_SHARED_TABLE(atrie);
	  return false;
	}
	unregister_waiting(mytid, atrie);
	if ( !atrie->tid && table_needs_work(atrie) )
	{ DEBUG(MSG_TABLING_SHARED,
		print_answer_table(atrie, "stealing abandonned trie"));
	  take_trie(atrie, mytid);
	} else
	{ goto complete;
	}
      } else if ( table_needs_work(atrie) )
      { DEBUG(MSG_TABLING_SHARED,
	      print_answer_table(atrie, "claiming"));
	take_trie(atrie, mytid);
      } else					/* complete and valid */
      { complete:
	if ( clrefp )
	{ if ( !(clref=atrie->clause) )
	  { Procedure proc = ((flags&AT_MODED)
				      ? GD->procedures.trie_gen_compiled3
				      : GD->procedures.trie_gen_compiled2);

	    clref = compile_trie(proc->definition, atrie);
	  }
	  pushVolatileAtom(clref);		/* see (*) above */
	  if ( clref != atrie->clause )
	    goto retry_shared;
	  *clrefp = clref;
	}
      }
      UNLOCK_SHARED_TABLE(atrie);
    }
  }

  return true;
}


static trie_array *
new_trie_array(void)
{ trie_array *a = allocHeapOrHalt(sizeof(*a));

  memset(a, 0, sizeof(*a));
  for(int i=0; i<=MSB(TRIE_ARRAY_PREALLOCATED); i++)
    a->blocks[i] = a->preallocated - 1;

  return a;
}


static void
free_trie_array(trie_array *a)
{ for(int i = 0; i < MAX_BLOCKS; i++)
  { if ( a->blocks[i] && a->blocks[i] != a->preallocated - 1 )
    { size_t bs = (size_t)1<<i;

      PL_free(a->blocks[i]+bs);
    }
  }

  freeHeap(a, sizeof(*a));
}


static void
register_waiting(int tid, trie *atrie)
{ trie_array *ta;
  size_t idx = MSB(tid);

  if ( !(ta=GD->tabling.waiting) )
  { ta = new_trie_array();
    if ( !COMPARE_AND_SWAP_PTR(&GD->tabling.waiting, NULL, ta) )
    { freeHeap(ta, sizeof(*ta));
      ta = GD->tabling.waiting;
    }
  }

  if ( !ta->blocks[idx] )
  { if ( !ta->blocks[idx] )
    { size_t bs = (size_t)1<<idx;
      trie **newblock;

      if ( !(newblock=PL_malloc_uncollectable(bs*sizeof(trie*))) )
	outOfCore();

      memset(newblock, 0, bs*sizeof(trie*));
      if ( !COMPARE_AND_SWAP_PTR(&ta->blocks[idx], NULL, newblock-bs) )
	PL_free(newblock);
    }
  }

  ta->blocks[idx][tid] = atrie;
}


static void
unregister_waiting(int tid, trie *atrie)
{ size_t idx = MSB(tid);

  GD->tabling.waiting->blocks[idx][tid] = NULL;
}


static trie *
thread_waits_for_trie(int tid)
{ trie_array *ta;

  if ( (ta=GD->tabling.waiting) )
  { size_t idx = MSB(tid);

    if ( ta->blocks[idx] )
      return ta->blocks[idx][tid];
  }

  return NULL;
}


/* - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - -
is_deadlock() succeeds if  the  proposed  situation   would  lead  to  a
deadlock.
- - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - */

static void
stat_deadlock(trie *atrie)
{
#if O_TRIE_STATS
  int mytid = atrie->tid;
  trie *t = NULL;
  int tid = mytid;

  TRIE_STAT_INC(atrie, deadlock);

  for(;;)
  { t = thread_waits_for_trie(tid);
    if ( t )
    { TRIE_STAT_INC(t, deadlock);
      tid = t->tid;
    }

    if ( !t || !tid )
      return;
    if ( tid == mytid )
      return;
  }
#endif
}


static int
is_deadlock(trie *atrie)
{ int mytid = atrie->tid;
  trie *t = NULL;
  int tid = mytid;

  for(;;)
  { t = thread_waits_for_trie(tid);
    if ( t )
      tid = t->tid;

    if ( !t || !tid )
      return false;
    if ( tid == mytid )
    { stat_deadlock(atrie);
      return true;
    }
  }
}


static int
wait_for_table_to_complete(trie *atrie)
{ DEBUG(MSG_TABLING_SHARED,
	print_answer_table(atrie, "waiting for %d to complete", atrie->tid));

  do
  { if ( cv_wait(&GD->tabling.cvar, &GD->tabling.mutex.mutex) == CV_INTR )
    { if ( PL_handle_signals() < 0 )
      { DEBUG(MSG_TABLING_SHARED,
	      print_answer_table(atrie, "Ready (interrupted"));
	return false;
      }
    }
  } while( atrie->tid != 0 );

  DEBUG(MSG_TABLING_SHARED,
	print_answer_table(atrie,
			   table_needs_work(atrie) ? "Ready (abandonned)"
						   : "Ready (completed)"));

  return true;
}
#endif /*O_PLMT*/


		 /*******************************
		 *	     UNTABLE		*
		 *******************************/

/* - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - -
This predicate is called for clauses   from  M:'$tabled'(Head, Mode) are
deleted during reconsult. It is called from the fixup phase of reloading
a file (see pl-srcfile.c) and we may not use any error condition.
- - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - */

void
untable_from_clause(Clause cl)
{ if ( cl->codes[0] == encode(H_FUNCTOR) )
  { GET_LD
    functor_t f = (functor_t)cl->codes[1];
    Module m = cl->predicate->module;
    Procedure proc = isCurrentProcedure(f, m);

    if ( proc && !callEventHook(PLEV_UNTABLE, proc) )
      fatalError("Failed to register untable event\n");
  } else
  { Sdprintf("WARNING: untable_from_clause(): unexpected clause\n");
  }
}

		 /*******************************
		 *	       INIT		*
		 *******************************/

void
initTabling(void)
{ GET_LD

#ifdef O_PLMT
  initSimpleMutex(&GD->tabling.mutex, "L_SHARED_TABLING");
  cv_init(&GD->tabling.cvar, NULL);
#endif

  LD->tabling.restraint.max_table_subgoal_size_action  = ATOM_error;
  LD->tabling.restraint.max_table_subgoal_size	       = (size_t)-1;
  LD->tabling.restraint.max_table_answer_size_action   = ATOM_error;
  LD->tabling.restraint.max_table_answer_size	       = (size_t)-1;
  LD->tabling.restraint.max_answers_for_subgoal_action = ATOM_error;
  LD->tabling.restraint.max_answers_for_subgoal	       = (size_t)-1;

  LD->tabling.in_assert_propagation = false;

  setPrologFlag("max_table_subgoal_size_action",  FT_ATOM,    "error");
  setPrologFlag("max_table_answer_size_action",	  FT_ATOM,    "error");
  setPrologFlag("max_answers_for_subgoal_action", FT_ATOM,    "error");
  setPrologFlag("max_table_subgoal_size",	  FT_INTEGER, (intptr_t)-1);
  setPrologFlag("max_table_answer_size",	  FT_INTEGER, (intptr_t)-1);
  setPrologFlag("max_answers_for_subgoal",	  FT_INTEGER, (intptr_t)-1);
  setPrologFlag("table_monotonic",		  FT_ATOM,    "eager");
}

void
cleanupTabling(void)
{ memset(fast_ret_functor, 0, sizeof(fast_ret_functor));

#ifdef O_PLMT
  clear_variant_table(&GD->tabling.variant_table);

  deleteSimpleMutex(&GD->tabling.mutex);
  cv_destroy(&GD->tabling.cvar);

  if ( GD->tabling.node_pool )
  { free_alloc_pool(GD->tabling.node_pool);
    GD->tabling.node_pool = NULL;
  }

  if ( GD->tabling.waiting )
  { free_trie_array(GD->tabling.waiting);
    GD->tabling.waiting = NULL;
  }
#endif
}


		 /*******************************
		 *      PUBLISH PREDICATES	*
		 *******************************/

#define NDET PL_FA_NONDETERMINISTIC
#define META PL_FA_TRANSPARENT

BeginPredDefs(tabling)
  PRED_DEF("$tbl_pop_worklist",		2, tbl_pop_worklist,	     0)
  PRED_DEF("$tbl_wkl_add_answer",	4, tbl_wkl_add_answer,	     0)
  PRED_DEF("$tbl_wkl_make_follower",    1, tbl_wkl_make_follower,    0)
  PRED_DEF("$tbl_wkl_add_suspension",	2, tbl_wkl_add_suspension,   0)
  PRED_DEF("$tbl_wkl_add_suspension",	3, tbl_wkl_add_suspension,   0)
  PRED_DEF("$tbl_wkl_done",		1, tbl_wkl_done,	     0)
  PRED_DEF("$tbl_wkl_negative",		1, tbl_wkl_negative,	     0)
  PRED_DEF("$tbl_wkl_is_false",		1, tbl_wkl_is_false,	     0)
  PRED_DEF("$tbl_wkl_answer_trie",	2, tbl_wkl_answer_trie,      0)
  PRED_DEF("$tbl_wkl_work",		6, tbl_wkl_work,          NDET)
  PRED_DEF("$tbl_variant_table",	6, tbl_variant_table,	     0)
  PRED_DEF("$tbl_abstract_table",       6, tbl_abstract_table,       0)
  PRED_DEF("$tbl_existing_variant_table", 5, tbl_existing_variant_table, 0)
  PRED_DEF("$tbl_moded_variant_table",	6, tbl_moded_variant_table,  0)
#ifdef O_PLMT
  PRED_DEF("$tbl_variant_table",        1, tbl_variant_table,	  NDET)
#else
  PRED_DEF("$tbl_variant_table",        1, tbl_local_variant_table,  0)
#endif
  PRED_DEF("$tbl_local_variant_table",  1, tbl_local_variant_table,  0)
  PRED_DEF("$tbl_global_variant_table", 1, tbl_global_variant_table, 0)
  PRED_DEF("$tbl_table_status",         2, tbl_table_status,         0)
  PRED_DEF("$tbl_table_status",		4, tbl_table_status,	     0)
  PRED_DEF("$tbl_table_pi",             2, tbl_table_pi,	     0)
  PRED_DEF("$tbl_table_complete_all",	3, tbl_table_complete_all,   0)
  PRED_DEF("$tbl_free_component",       1, tbl_free_component,       0)
  PRED_DEF("$tbl_table_discard_all",    1, tbl_table_discard_all,    0)
  PRED_DEF("$tbl_abolish_local_tables", 0, tbl_abolish_local_tables, 0)
  PRED_DEF("$tbl_destroy_table",        1, tbl_destroy_table,        0)
  PRED_DEF("$tbl_trienode",             1, tbl_trienode,             0)
  PRED_DEF("$tbl_is_trienode",          1, tbl_is_trienode,          0)
  PRED_DEF("$tbl_delay_list",           1, tbl_delay_list,           0)
  PRED_DEF("$tbl_set_delay_list",       1, tbl_set_delay_list,       0)
  PRED_DEF("$tbl_add_global_delays",    2, tbl_add_global_delays,    0)

  PRED_DEF("$tbl_scc",                  1, tbl_scc,                  0)
  PRED_DEF("$tbl_scc_data",             2, tbl_scc_data,             0)
  PRED_DEF("$tbl_worklist_data",        2, tbl_worklist_data,        0)
  PRED_DEF("$tbl_wkl_table",            2, tbl_wkl_table,	     0)
  PRED_DEF("$tbl_answer",               3, tbl_answer,            NDET)
  PRED_DEF("$tbl_answer_c",             4, tbl_answer_c,          NDET)
  PRED_DEF("$tbl_answer_dl",		3, tbl_answer_dl,         NDET)
  PRED_DEF("$tbl_answer_dl",            4, tbl_answer_dl,	  NDET)
  PRED_DEF("$tbl_answer_update_dl",     2, tbl_answer_update_dl,  NDET)
  PRED_DEF("$tbl_answer_update_dl",     3, tbl_answer_update_dl,  NDET)
  PRED_DEF("$tbl_force_truth_value",    3, tbl_force_truth_value,    0)
  PRED_DEF("$tbl_set_answer_completed", 1, tbl_set_answer_completed, 0)
  PRED_DEF("$tbl_is_answer_completed",  1, tbl_is_answer_completed,  0)
  PRED_DEF("$tnot_implementation",      2, tnot_implementation,   META)
  PRED_DEF("$tbl_implementation",       2, tbl_implementation,    META)
  PRED_DEF("$is_answer_trie",		2, is_answer_trie,	     0)

  PRED_DEF("$idg_add_dyncall",          1, idg_add_dyncall,          0)
  PRED_DEF("$idg_add_edge",             1, idg_add_edge,             0)
  PRED_DEF("$idg_set_current",          1, idg_set_current,          0)
  PRED_DEF("$idg_set_current",          2, idg_set_current,          0)
  PRED_DEF("$idg_reset_current",        0, idg_reset_current,        0)
  PRED_DEF("$idg_edge",                 3, idg_edge,              NDET)
  PRED_DEF("$idg_changed",              1, idg_changed,              0)
  PRED_DEF("$idg_falsecount",           2, idg_falsecount,           0)
  PRED_DEF("$idg_forced",               1, idg_forced,               0)
  PRED_DEF("$idg_set_falsecount",       2, idg_set_falsecount,       0)
  PRED_DEF("$idg_false_edge",           3, idg_false_edge,	  NDET)

  PRED_DEF("$tbl_reeval_prepare_top",	2, tbl_reeval_prepare_top,   0)
  PRED_DEF("$tbl_reeval_prepare",       2, tbl_reeval_prepare,	     0)
  PRED_DEF("$tbl_reeval_abandon",       1, tbl_reeval_abandon,       0)
  PRED_DEF("$tbl_reeval_wait",          2, tbl_reeval_wait,          0)

  PRED_DEF("$tbl_monotonic_add_answer", 2, tbl_monotonic_add_answer, 0)
  PRED_DEF("$idg_add_monotonic_dep",    3, idg_add_monotonic_dep,    0)
  PRED_DEF("$idg_add_mono_dyn_dep",     3, idg_add_mono_dyn_dep,     0)
  PRED_DEF("$idg_mono_affects",         3, idg_mono_affects,      NDET)
  PRED_DEF("$idg_mono_affects_eager",   3, idg_mono_affects_eager,NDET)
  PRED_DEF("$idg_mono_affects_lazy",    5, idg_mono_affects_lazy, NDET)
  PRED_DEF("$tbl_propagate_start",      1, tbl_propagate_start,      0)
  PRED_DEF("$tbl_propagate_end",        1, tbl_propagate_end,        0)
  PRED_DEF("$tbl_collect_mono_dep",     0, tbl_collect_mono_dep,     0)
  PRED_DEF("$mono_idg_changed",         2, mono_idg_changed,	     0)
  PRED_DEF("$mono_reeval_prepare",      2, mono_reeval_prepare,	     0)
  PRED_DEF("$mono_reeval_done",		3, mono_reeval_done,	     0)
  PRED_DEF("$idg_mono_empty_queue",     2, idg_mono_empty_queue,     0)
  PRED_DEF("$idg_mono_invalidate",      1, idg_mono_invalidate,	     0)
  PRED_DEF("$tbl_node_answer",          2, tbl_node_answer,	     0)
EndPredDefs
